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firebird-mirror/src/dsql/StmtNodes.cpp

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/*
* The contents of this file are subject to the Interbase Public
* License Version 1.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy
* of the License at http://www.Inprise.com/IPL.html
*
* Software distributed under the License is distributed on an
* "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, either express
* or implied. See the License for the specific language governing
* rights and limitations under the License.
*
* The Original Code was created by Inprise Corporation
* and its predecessors. Portions created by Inprise Corporation are
* Copyright (C) Inprise Corporation.
*
* All Rights Reserved.
* Contributor(s): ______________________________________.
* Adriano dos Santos Fernandes - refactored from pass1.cpp, gen.cpp, cmp.cpp, par.cpp and exe.cpp
*/
#include "firebird.h"
#include "../common/classes/BaseStream.h"
#include "../common/classes/MsgPrint.h"
#include "../common/classes/VaryStr.h"
#include "../dsql/BoolNodes.h"
#include "../dsql/ExprNodes.h"
#include "../dsql/StmtNodes.h"
#include "../jrd/align.h"
#include "../jrd/blr.h"
#include "../jrd/tra.h"
#include "../jrd/Function.h"
#include "../jrd/Optimizer.h"
#include "../jrd/RecordSourceNodes.h"
#include "../jrd/VirtualTable.h"
#include "../jrd/extds/ExtDS.h"
#include "../jrd/recsrc/RecordSource.h"
#include "../jrd/recsrc/Cursor.h"
#include "../jrd/trace/TraceManager.h"
#include "../jrd/trace/TraceJrdHelpers.h"
#include "../jrd/cmp_proto.h"
#include "../jrd/dfw_proto.h"
#include "../jrd/dpm_proto.h"
#include "../jrd/evl_proto.h"
#include "../jrd/exe_proto.h"
#include "../jrd/ext_proto.h"
#include "../jrd/idx_proto.h"
#include "../jrd/met_proto.h"
#include "../jrd/mov_proto.h"
#include "../jrd/par_proto.h"
#include "../jrd/rlck_proto.h"
#include "../jrd/tra_proto.h"
#include "../jrd/scl_proto.h"
#include "../dsql/ddl_proto.h"
#include "../dsql/metd_proto.h"
#include "../jrd/vio_proto.h"
#include "../dsql/errd_proto.h"
#include "../dsql/gen_proto.h"
#include "../dsql/make_proto.h"
#include "../dsql/pass1_proto.h"
using namespace Firebird;
using namespace Jrd;
namespace Jrd {
template <typename T> static void dsqlExplodeFields(dsql_rel* relation, Array<NestConst<T> >& fields);
static dsql_par* dsqlFindDbKey(const dsql_req*, const RelationSourceNode*);
static dsql_par* dsqlFindRecordVersion(const dsql_req*, const RelationSourceNode*);
static const dsql_msg* dsqlGenDmlHeader(DsqlCompilerScratch*, RseNode*);
static dsql_ctx* dsqlGetContext(const RecordSourceNode* node);
static void dsqlGetContexts(DsqlContextStack& contexts, const RecordSourceNode* node);
static StmtNode* dsqlNullifyReturning(DsqlCompilerScratch*, StmtNode* input, bool returnList);
static void dsqlFieldAppearsOnce(const Array<NestConst<ValueExprNode> >& values, const char* command);
static ValueListNode* dsqlPassArray(DsqlCompilerScratch*, ValueListNode*);
static dsql_ctx* dsqlPassCursorContext(DsqlCompilerScratch*, const MetaName&, const RelationSourceNode*);
static RseNode* dsqlPassCursorReference(DsqlCompilerScratch*, const MetaName&, RelationSourceNode*);
static VariableNode* dsqlPassHiddenVariable(DsqlCompilerScratch* dsqlScratch, ValueExprNode* expr);
static USHORT dsqlPassLabel(DsqlCompilerScratch* dsqlScratch, bool breakContinue, MetaName* label);
static StmtNode* dsqlProcessReturning(DsqlCompilerScratch*, ReturningClause*, StmtNode*);
static void dsqlSetParameterName(ExprNode*, const ValueExprNode*, const dsql_rel*);
static void dsqlSetParametersName(CompoundStmtNode*, const RecordSourceNode*);
static void cleanupRpb(thread_db* tdbb, record_param* rpb);
static void makeValidation(thread_db* tdbb, CompilerScratch* csb, StreamType stream,
Array<ValidateInfo>& validations);
static StmtNode* pass1ExpandView(thread_db* tdbb, CompilerScratch* csb, StreamType orgStream,
StreamType newStream, bool remap);
static RelationSourceNode* pass1Update(thread_db* tdbb, CompilerScratch* csb, jrd_rel* relation,
const trig_vec* trigger, StreamType stream, StreamType updateStream, SecurityClass::flags_t priv,
jrd_rel* view, StreamType viewStream, StreamType viewUpdateStream);
static void pass1Validations(thread_db* tdbb, CompilerScratch* csb, Array<ValidateInfo>& validations);
static void postTriggerAccess(CompilerScratch* csb, jrd_rel* ownerRelation,
ExternalAccess::exa_act operation, jrd_rel* view);
static void preModifyEraseTriggers(thread_db* tdbb, trig_vec** trigs,
StmtNode::WhichTrigger whichTrig, record_param* rpb, record_param* rec, TriggerAction op);
static void validateExpressions(thread_db* tdbb, const Array<ValidateInfo>& validations);
} // namespace Jrd
namespace
{
// Node copier that remaps the field id 0 of stream 0 to a given field id.
class RemapFieldNodeCopier : public NodeCopier
{
public:
RemapFieldNodeCopier(CompilerScratch* aCsb, StreamType* aRemap, USHORT aFldId)
: NodeCopier(aCsb, aRemap),
fldId(aFldId)
{
}
protected:
virtual USHORT getFieldId(const FieldNode* field)
{
if (field->byId && field->fieldId == 0 && field->fieldStream == 0)
return fldId;
return NodeCopier::getFieldId(field);
}
private:
USHORT fldId;
};
class ReturningProcessor
{
public:
// Play with contexts for RETURNING purposes.
// Its assumed that oldContext is already on the stack.
// Changes oldContext name to "OLD".
ReturningProcessor(DsqlCompilerScratch* aScratch, dsql_ctx* aOldContext, dsql_ctx* modContext)
: scratch(aScratch),
oldContext(aOldContext),
oldAlias(oldContext->ctx_alias),
oldInternalAlias(oldContext->ctx_internal_alias),
autoFlags(&oldContext->ctx_flags, oldContext->ctx_flags | CTX_system | CTX_returning)
{
// Clone the modify/old context and push with name "NEW" in a greater scope level.
dsql_ctx* newContext = FB_NEW(scratch->getPool()) dsql_ctx(scratch->getPool());
if (modContext)
{
// Push the modify context in the same scope level.
scratch->context->push(modContext);
*newContext = *modContext;
newContext->ctx_flags |= CTX_system;
}
else
{
// Create the target (= OLD) context and push it on the stack.
dsql_ctx* targetContext = FB_NEW(scratch->getPool()) dsql_ctx(scratch->getPool());
*targetContext = *oldContext;
targetContext->ctx_flags &= ~CTX_system; // resolve unqualified fields
scratch->context->push(targetContext);
// This is NEW in the context of a DELETE. Mark it as NULL.
*newContext = *oldContext;
newContext->ctx_flags |= CTX_null;
}
oldContext->ctx_alias = oldContext->ctx_internal_alias = OLD_CONTEXT_NAME;
newContext->ctx_alias = newContext->ctx_internal_alias = NEW_CONTEXT_NAME;
newContext->ctx_flags |= CTX_returning;
scratch->context->push(newContext);
}
~ReturningProcessor()
{
oldContext->ctx_alias = oldAlias;
oldContext->ctx_internal_alias = oldInternalAlias;
// Restore the context stack.
scratch->context->pop();
scratch->context->pop();
}
// Process the RETURNING clause.
StmtNode* process(ReturningClause* node, StmtNode* stmtNode)
{
return dsqlProcessReturning(scratch, node, stmtNode);
}
// Clone a RETURNING node without create duplicate parameters.
static StmtNode* clone(DsqlCompilerScratch* scratch, ReturningClause* unprocessed, StmtNode* processed)
{
if (!processed)
return NULL;
// nod_returning was already processed
CompoundStmtNode* processedStmt = processed->as<CompoundStmtNode>();
fb_assert(processed);
// And we create a RETURNING node where the targets are already processed.
CompoundStmtNode* newNode =
FB_NEW(scratch->getPool()) CompoundStmtNode(scratch->getPool());
NestConst<ValueExprNode>* srcPtr = unprocessed->first->items.begin();
NestConst<StmtNode>* dstPtr = processedStmt->statements.begin();
for (const NestConst<ValueExprNode>* const end = unprocessed->first->items.end();
srcPtr != end;
++srcPtr, ++dstPtr)
{
AssignmentNode* temp = FB_NEW(scratch->getPool()) AssignmentNode(scratch->getPool());
temp->asgnFrom = *srcPtr;
temp->asgnTo = (*dstPtr)->as<AssignmentNode>()->asgnTo;
newNode->statements.add(temp);
}
return newNode;
}
private:
DsqlCompilerScratch* scratch;
dsql_ctx* oldContext;
string oldAlias, oldInternalAlias;
AutoSetRestore<USHORT> autoFlags;
};
} // namespace
//--------------------
namespace Jrd {
StmtNode* SavepointEncloseNode::make(MemoryPool& pool, DsqlCompilerScratch* dsqlScratch, StmtNode* node)
{
if (dsqlScratch->errorHandlers)
{
node = FB_NEW(pool) SavepointEncloseNode(pool, node);
node->dsqlPass(dsqlScratch);
}
return node;
}
string SavepointEncloseNode::internalPrint(NodePrinter& printer) const
{
DsqlOnlyStmtNode::internalPrint(printer);
NODE_PRINT(printer, stmt);
return "SavepointEncloseNode";
}
void SavepointEncloseNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_begin);
dsqlScratch->appendUChar(blr_start_savepoint);
stmt->genBlr(dsqlScratch);
dsqlScratch->appendUChar(blr_end_savepoint);
dsqlScratch->appendUChar(blr_end);
}
//--------------------
static RegisterNode<AssignmentNode> regAssignmentNode(blr_assignment);
DmlNode* AssignmentNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
AssignmentNode* node = FB_NEW(pool) AssignmentNode(pool);
node->asgnFrom = PAR_parse_value(tdbb, csb);
node->asgnTo = PAR_parse_value(tdbb, csb);
return node;
}
void AssignmentNode::validateTarget(CompilerScratch* csb, const ValueExprNode* target)
{
const FieldNode* fieldNode;
if ((fieldNode = target->as<FieldNode>()))
{
CompilerScratch::csb_repeat* tail = &csb->csb_rpt[fieldNode->fieldStream];
// Assignments to the OLD context are prohibited for all trigger types.
if ((tail->csb_flags & csb_trigger) && fieldNode->fieldStream == OLD_CONTEXT_VALUE)
ERR_post(Arg::Gds(isc_read_only_field));
// Assignments to the NEW context are prohibited for post-action triggers.
if ((tail->csb_flags & csb_trigger) && fieldNode->fieldStream == NEW_CONTEXT_VALUE &&
(csb->csb_g_flags & csb_post_trigger))
{
ERR_post(Arg::Gds(isc_read_only_field));
}
// Assignment to cursor fields are always prohibited.
// But we cannot detect FOR cursors here. They are treated in dsqlPass.
if (fieldNode->cursorNumber.specified)
ERR_post(Arg::Gds(isc_read_only_field));
}
else if (!(target->is<ParameterNode>() || target->is<VariableNode>() || target->is<NullNode>()))
ERR_post(Arg::Gds(isc_read_only_field));
}
void AssignmentNode::dsqlValidateTarget(const ValueExprNode* target)
{
const DerivedFieldNode* fieldNode = target->as<DerivedFieldNode>();
if (fieldNode && fieldNode->context &&
(fieldNode->context->ctx_flags & (CTX_system | CTX_cursor)) == CTX_cursor)
{
ERR_post(Arg::Gds(isc_read_only_field));
}
}
AssignmentNode* AssignmentNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
AssignmentNode* node = FB_NEW(getPool()) AssignmentNode(getPool());
node->asgnFrom = doDsqlPass(dsqlScratch, asgnFrom);
node->asgnTo = doDsqlPass(dsqlScratch, asgnTo);
dsqlValidateTarget(node->asgnTo);
// Try to force asgnFrom to be same type as asgnTo eg: ? = FIELD case
PASS1_set_parameter_type(dsqlScratch, node->asgnFrom, node->asgnTo, false);
// Try to force asgnTo to be same type as asgnFrom eg: FIELD = ? case
// Try even when the above call succeeded, because "asgnTo" may
// have sub-expressions that should be resolved.
PASS1_set_parameter_type(dsqlScratch, node->asgnTo, node->asgnFrom, false);
return node;
}
string AssignmentNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, asgnFrom);
NODE_PRINT(printer, asgnTo);
NODE_PRINT(printer, missing);
NODE_PRINT(printer, missing2);
return "AssignmentNode";
}
void AssignmentNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_assignment);
GEN_expr(dsqlScratch, asgnFrom);
GEN_expr(dsqlScratch, asgnTo);
}
AssignmentNode* AssignmentNode::copy(thread_db* tdbb, NodeCopier& copier) const
{
AssignmentNode* node = FB_NEW(*tdbb->getDefaultPool()) AssignmentNode(*tdbb->getDefaultPool());
node->asgnFrom = copier.copy(tdbb, asgnFrom);
node->asgnTo = copier.copy(tdbb, asgnTo);
node->missing = copier.copy(tdbb, missing);
node->missing2 = copier.copy(tdbb, missing2);
return node;
}
AssignmentNode* AssignmentNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
ValueExprNode* sub = asgnFrom;
FieldNode* fieldNode;
StreamType stream;
CompilerScratch::csb_repeat* tail;
if ((fieldNode = sub->as<FieldNode>()))
{
stream = fieldNode->fieldStream;
jrd_fld* field = MET_get_field(csb->csb_rpt[stream].csb_relation, fieldNode->fieldId);
if (field)
missing2 = field->fld_missing_value;
}
sub = asgnTo;
if ((fieldNode = sub->as<FieldNode>()))
{
stream = fieldNode->fieldStream;
tail = &csb->csb_rpt[stream];
jrd_fld* field = MET_get_field(tail->csb_relation, fieldNode->fieldId);
if (field && field->fld_missing_value)
missing = field->fld_missing_value;
}
doPass1(tdbb, csb, asgnFrom.getAddress());
doPass1(tdbb, csb, asgnTo.getAddress());
doPass1(tdbb, csb, missing.getAddress());
// ASF: No idea why we do not call pass1 for missing2.
return this;
}
AssignmentNode* AssignmentNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, asgnFrom.getAddress());
ExprNode::doPass2(tdbb, csb, asgnTo.getAddress());
ExprNode::doPass2(tdbb, csb, missing.getAddress());
ExprNode::doPass2(tdbb, csb, missing2.getAddress());
validateTarget(csb, asgnTo);
return this;
}
const StmtNode* AssignmentNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
EXE_assignment(tdbb, this);
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<BlockNode> regBlockNode(blr_block);
DmlNode* BlockNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
BlockNode* node = FB_NEW(pool) BlockNode(pool);
node->action = PAR_parse_stmt(tdbb, csb);
StmtNodeStack stack;
while (csb->csb_blr_reader.peekByte() != blr_end)
stack.push(PAR_parse_stmt(tdbb, csb));
csb->csb_blr_reader.getByte(); // skip blr_end
node->handlers = PAR_make_list(tdbb, stack);
return node;
}
StmtNode* BlockNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
if (!handlers && !dsqlScratch->errorHandlers)
{
CompoundStmtNode* node = FB_NEW(getPool()) CompoundStmtNode(getPool());
node->statements.add(action->dsqlPass(dsqlScratch));
return node;
}
BlockNode* node = FB_NEW(getPool()) BlockNode(getPool());
if (handlers)
++dsqlScratch->errorHandlers;
node->action = action->dsqlPass(dsqlScratch);
if (handlers)
{
node->handlers = handlers->dsqlPass(dsqlScratch);
--dsqlScratch->errorHandlers;
}
return node;
}
string BlockNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, action);
NODE_PRINT(printer, handlers);
return "BlockNode";
}
void BlockNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_block);
action->genBlr(dsqlScratch);
if (handlers)
{
const NestConst<StmtNode>* const end = handlers->statements.end();
for (NestConst<StmtNode>* ptr = handlers->statements.begin(); ptr != end; ++ptr)
(*ptr)->genBlr(dsqlScratch);
}
dsqlScratch->appendUChar(blr_end);
}
BlockNode* BlockNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, action.getAddress());
doPass1(tdbb, csb, handlers.getAddress());
return this;
}
BlockNode* BlockNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, action.getAddress(), this);
doPass2(tdbb, csb, handlers.getAddress(), this);
impureOffset = CMP_impure(csb, sizeof(SLONG));
return this;
}
const StmtNode* BlockNode::execute(thread_db* tdbb, jrd_req* request, ExeState* exeState) const
{
jrd_tra* transaction = request->req_transaction;
jrd_tra* sysTransaction = request->req_attachment->getSysTransaction();
SLONG count;
switch (request->req_operation)
{
case jrd_req::req_evaluate:
if (transaction != sysTransaction)
{
VIO_start_save_point(tdbb, transaction);
const Savepoint* save_point = transaction->tra_save_point;
count = save_point->sav_number;
*request->getImpure<SLONG>(impureOffset) = count;
}
return action;
case jrd_req::req_unwind:
{
if (request->req_flags & (req_leave | req_continue_loop))
{
// Although the req_operation is set to req_unwind,
// it's not an error case if req_leave/req_continue_loop bit is set.
// req_leave/req_continue_loop bit indicates that we hit an EXIT or
// BREAK/LEAVE/CONTINUE statement in the SP/trigger code.
// Do not perform the error handling stuff.
if (transaction != sysTransaction)
{
count = *request->getImpure<SLONG>(impureOffset);
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= count)
{
VIO_verb_cleanup(tdbb, transaction);
}
}
return parentStmt;
}
if (transaction != sysTransaction)
{
count = *request->getImpure<SLONG>(impureOffset);
// Since there occurred an error (req_unwind), undo all savepoints
// up to, but not including, the savepoint of this block. The
// savepoint of this block will be dealt with below.
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number > count)
{
++transaction->tra_save_point->sav_verb_count;
VIO_verb_cleanup(tdbb, transaction);
}
}
const StmtNode* temp;
if (handlers)
{
temp = parentStmt;
const NestConst<StmtNode>* ptr = handlers->statements.begin();
for (const NestConst<StmtNode>* const end = handlers->statements.end();
ptr != end;
++ptr)
{
const ErrorHandlerNode* handlerNode = (*ptr)->as<ErrorHandlerNode>();
const ExceptionArray& xcpNode = handlerNode->conditions;
if (testAndFixupError(tdbb, request, xcpNode))
{
request->req_operation = jrd_req::req_evaluate;
temp = handlerNode->action;
exeState->errorPending = false;
// On entering looper exeState->oldRequest etc. are saved.
// On recursive calling we will loose the actual old
// request for that invocation of looper. Avoid this.
{
Jrd::ContextPoolHolder contextLooper(tdbb, exeState->oldPool);
tdbb->setRequest(exeState->oldRequest);
fb_assert(request->req_caller == exeState->oldRequest);
request->req_caller = NULL;
// Save the previous state of req_error_handler
// bit. We need to restore it later. This is
// necessary if the error handler is deeply nested.
const ULONG prev_req_error_handler =
request->req_flags & req_error_handler;
request->req_flags |= req_error_handler;
temp = EXE_looper(tdbb, request, temp);
request->req_flags &= ~req_error_handler;
request->req_flags |= prev_req_error_handler;
// Re-assign the transaction pointer, as the active transaction
// could change in the meantime (inside the looper)
transaction = request->req_transaction;
// Note: Previously the above call "temp = looper (tdbb, request, temp);"
// never returned back till the tree was executed completely. Now that
// the looper has changed its behaviour such that it returns back after
// handling error. This makes it necessary that the jmpbuf be reset
// so that looper can proceede with the processing of execution tree.
// If this is not done then anymore errors will take the engine out of
// looper there by abruptly terminating the processing.
exeState->catchDisabled = false;
tdbb->setRequest(request);
fb_assert(request->req_caller == NULL);
request->req_caller = exeState->oldRequest;
}
// The error is dealt with by the application, cleanup
// this block's savepoint.
if (transaction != sysTransaction)
{
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= count)
{
VIO_verb_cleanup(tdbb, transaction);
}
}
}
}
}
else
temp = parentStmt;
// If the application didn't have an error handler, then
// the error will still be pending. Undo the block by
// using its savepoint.
if (exeState->errorPending && transaction != sysTransaction)
{
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= count)
{
++transaction->tra_save_point->sav_verb_count;
VIO_verb_cleanup(tdbb, transaction);
}
}
return temp;
}
case jrd_req::req_return:
if (transaction != sysTransaction)
{
count = *request->getImpure<SLONG>(impureOffset);
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= count)
{
VIO_verb_cleanup(tdbb, transaction);
}
}
default:
return parentStmt;
}
fb_assert(false);
return NULL;
}
// Test for match of current state with list of error conditions. Fix type and code of the exception.
bool BlockNode::testAndFixupError(thread_db* tdbb, jrd_req* request, const ExceptionArray& conditions)
{
if (tdbb->tdbb_flags & TDBB_sys_error)
return false;
Jrd::FbStatusVector* statusVector = tdbb->tdbb_status_vector;
bool found = false;
for (USHORT i = 0; i < conditions.getCount(); i++)
{
switch (conditions[i].type)
{
case ExceptionItem::SQL_CODE:
{
const SSHORT sqlcode = gds__sqlcode(statusVector->getErrors());
if (sqlcode == conditions[i].code)
found = true;
}
break;
case ExceptionItem::SQL_STATE:
{
FB_SQLSTATE_STRING sqlstate;
fb_sqlstate(sqlstate, statusVector->getErrors());
if (conditions[i].name == sqlstate)
found = true;
}
break;
case ExceptionItem::GDS_CODE:
if (statusVector->getErrors()[1] == conditions[i].code)
found = true;
break;
case ExceptionItem::XCP_CODE:
// Look at set_error() routine to understand how the
// exception ID info is encoded inside the status vector.
if ((statusVector->getErrors()[1] == isc_except) &&
(statusVector->getErrors()[3] == conditions[i].code))
{
found = true;
}
break;
case ExceptionItem::XCP_DEFAULT:
found = true;
break;
default:
fb_assert(false);
}
if (found)
{
request->req_last_xcp.init(statusVector);
fb_utils::init_status(statusVector);
break;
}
}
return found;
}
//--------------------
static RegisterNode<CompoundStmtNode> regCompoundStmtNode(blr_begin);
DmlNode* CompoundStmtNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
CompoundStmtNode* node = FB_NEW(pool) CompoundStmtNode(pool);
if (csb->csb_currentForNode)
csb->csb_currentForNode->parBlrBeginCnt++;
while (csb->csb_blr_reader.peekByte() != blr_end)
node->statements.add(PAR_parse_stmt(tdbb, csb));
csb->csb_blr_reader.getByte(); // skip blr_end
return node;
}
CompoundStmtNode* CompoundStmtNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
if (++dsqlScratch->nestingLevel > DsqlCompilerScratch::MAX_NESTING)
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-901) <<
Arg::Gds(isc_imp_exc) <<
Arg::Gds(isc_dsql_max_nesting) << Arg::Num(DsqlCompilerScratch::MAX_NESTING));
}
CompoundStmtNode* node = FB_NEW(getPool()) CompoundStmtNode(getPool());
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
{
StmtNode* ptr = *i;
ptr = ptr->dsqlPass(dsqlScratch);
node->statements.add(ptr);
}
--dsqlScratch->nestingLevel;
return node;
}
string CompoundStmtNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, statements);
NODE_PRINT(printer, onlyAssignments);
return "CompoundStmtNode";
}
void CompoundStmtNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_begin);
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
(*i)->genBlr(dsqlScratch);
dsqlScratch->appendUChar(blr_end);
}
CompoundStmtNode* CompoundStmtNode::copy(thread_db* tdbb, NodeCopier& copier) const
{
CompoundStmtNode* node = FB_NEW(*tdbb->getDefaultPool()) CompoundStmtNode(*tdbb->getDefaultPool());
node->onlyAssignments = onlyAssignments;
NestConst<StmtNode>* j = node->statements.getBuffer(statements.getCount());
for (const NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i, ++j)
*j = copier.copy(tdbb, *i);
return node;
}
CompoundStmtNode* CompoundStmtNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
doPass1(tdbb, csb, i->getAddress());
return this;
}
CompoundStmtNode* CompoundStmtNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
doPass2(tdbb, csb, i->getAddress(), this);
impureOffset = CMP_impure(csb, sizeof(impure_state));
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
{
if (!StmtNode::is<AssignmentNode>(i->getObject()))
return this;
}
onlyAssignments = true;
return this;
}
const StmtNode* CompoundStmtNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
const NestConst<StmtNode>* end = statements.end();
if (onlyAssignments)
{
if (request->req_operation == jrd_req::req_evaluate)
{
for (const NestConst<StmtNode>* i = statements.begin(); i != end; ++i)
{
const StmtNode* stmt = i->getObject();
if (stmt->hasLineColumn)
{
request->req_src_line = stmt->line;
request->req_src_column = stmt->column;
}
EXE_assignment(tdbb, static_cast<const AssignmentNode*>(stmt));
}
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
impure_state* impure = request->getImpure<impure_state>(impureOffset);
switch (request->req_operation)
{
case jrd_req::req_evaluate:
impure->sta_state = 0;
// fall into
case jrd_req::req_return:
case jrd_req::req_sync:
if (impure->sta_state < statements.getCount())
{
request->req_operation = jrd_req::req_evaluate;
return statements[impure->sta_state++];
}
request->req_operation = jrd_req::req_return;
// fall into
default:
return parentStmt;
}
}
//--------------------
static RegisterNode<ContinueLeaveNode> regContinueLeaveNodeContinue(blr_continue_loop);
static RegisterNode<ContinueLeaveNode> regContinueLeaveNodeLeave(blr_leave);
DmlNode* ContinueLeaveNode::parse(thread_db* /*tdbb*/, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
ContinueLeaveNode* node = FB_NEW(pool) ContinueLeaveNode(pool, blrOp);
node->labelNumber = csb->csb_blr_reader.getByte();
return node;
}
ContinueLeaveNode* ContinueLeaveNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
const char* cmd = blrOp == blr_continue_loop ? "CONTINUE" : "BREAK/LEAVE";
if (!dsqlScratch->loopLevel)
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
// Token unknown
Arg::Gds(isc_token_err) <<
Arg::Gds(isc_random) << cmd);
}
labelNumber = dsqlPassLabel(dsqlScratch, true, dsqlLabelName);
return this;
}
string ContinueLeaveNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, blrOp);
NODE_PRINT(printer, labelNumber);
NODE_PRINT(printer, dsqlLabelName);
return "ContinueLeaveNode";
}
void ContinueLeaveNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blrOp);
dsqlScratch->appendUChar(labelNumber);
}
const StmtNode* ContinueLeaveNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
request->req_operation = jrd_req::req_unwind;
request->req_label = labelNumber;
request->req_flags |= (blrOp == blr_continue_loop ? req_continue_loop : req_leave);
}
return parentStmt;
}
//--------------------
static RegisterNode<CursorStmtNode> regCursorStmtNode(blr_cursor_stmt);
DmlNode* CursorStmtNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
CursorStmtNode* node = FB_NEW(pool) CursorStmtNode(pool, csb->csb_blr_reader.getByte());
node->cursorNumber = csb->csb_blr_reader.getWord();
switch (node->cursorOp)
{
case blr_cursor_open:
case blr_cursor_close:
break;
case blr_cursor_fetch_scroll:
node->scrollOp = csb->csb_blr_reader.getByte();
node->scrollExpr = PAR_parse_value(tdbb, csb);
// fall into
case blr_cursor_fetch:
csb->csb_g_flags |= csb_reuse_context;
node->intoStmt = PAR_parse_stmt(tdbb, csb);
csb->csb_g_flags &= ~csb_reuse_context;
break;
default:
PAR_syntax_error(csb, "cursor operation clause");
}
return node;
}
CursorStmtNode* CursorStmtNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
// Verify if we're in an autonomous transaction.
if (dsqlScratch->flags & DsqlCompilerScratch::FLAG_IN_AUTO_TRANS_BLOCK)
{
const char* stmt = NULL;
switch (cursorOp)
{
case blr_cursor_open:
stmt = "OPEN CURSOR";
break;
case blr_cursor_close:
stmt = "CLOSE CURSOR";
break;
case blr_cursor_fetch:
case blr_cursor_fetch_scroll:
stmt = "FETCH CURSOR";
break;
}
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-901) <<
Arg::Gds(isc_dsql_unsupported_in_auto_trans) << Arg::Str(stmt));
}
// Resolve the cursor.
cursorNumber = PASS1_cursor_name(dsqlScratch, dsqlName,
DeclareCursorNode::CUR_TYPE_EXPLICIT, true)->cursorNumber;
// Process a scroll node, if exists.
if (scrollExpr)
scrollExpr = doDsqlPass(dsqlScratch, scrollExpr);
// Process an assignment node, if exists.
dsqlIntoStmt = dsqlPassArray(dsqlScratch, dsqlIntoStmt);
return this;
}
string CursorStmtNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlName);
NODE_PRINT(printer, dsqlIntoStmt);
NODE_PRINT(printer, cursorOp);
NODE_PRINT(printer, cursorNumber);
NODE_PRINT(printer, scrollOp);
NODE_PRINT(printer, scrollExpr);
NODE_PRINT(printer, intoStmt);
return "CursorStmtNode";
}
void CursorStmtNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_cursor_stmt);
dsqlScratch->appendUChar(cursorOp); // open, close, fetch [scroll]
dsqlScratch->appendUShort(cursorNumber);
if (cursorOp == blr_cursor_fetch_scroll)
{
dsqlScratch->appendUChar(scrollOp);
if (scrollExpr)
GEN_expr(dsqlScratch, scrollExpr);
else
dsqlScratch->appendUChar(blr_null);
}
DeclareCursorNode* cursor = NULL;
for (Array<DeclareCursorNode*>::iterator itr = dsqlScratch->cursors.begin();
itr != dsqlScratch->cursors.end();
++itr)
{
if ((*itr)->cursorNumber == cursorNumber)
cursor = *itr;
}
fb_assert(cursor);
// Assignment.
if (cursorOp == blr_cursor_fetch || cursorOp == blr_cursor_fetch_scroll)
dsqlScratch->appendUChar(blr_begin);
if (dsqlIntoStmt)
{
ValueListNode* list = cursor->rse->dsqlSelectList;
if (list->items.getCount() != dsqlIntoStmt->items.getCount())
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-313) <<
Arg::Gds(isc_dsql_count_mismatch));
}
NestConst<ValueExprNode>* ptr = list->items.begin();
NestConst<ValueExprNode>* end = list->items.end();
NestConst<ValueExprNode>* ptr_to = dsqlIntoStmt->items.begin();
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_FETCH;
while (ptr != end)
{
dsqlScratch->appendUChar(blr_assignment);
GEN_expr(dsqlScratch, *ptr++);
GEN_expr(dsqlScratch, *ptr_to++);
}
dsqlScratch->flags &= ~DsqlCompilerScratch::FLAG_FETCH;
}
if (cursorOp == blr_cursor_fetch || cursorOp == blr_cursor_fetch_scroll)
dsqlScratch->appendUChar(blr_end);
}
CursorStmtNode* CursorStmtNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, scrollExpr.getAddress());
doPass1(tdbb, csb, intoStmt.getAddress());
return this;
}
CursorStmtNode* CursorStmtNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, scrollExpr.getAddress());
doPass2(tdbb, csb, intoStmt.getAddress(), this);
return this;
}
const StmtNode* CursorStmtNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
fb_assert(cursorNumber < request->req_cursors.getCount());
const Cursor* const cursor = request->req_cursors[cursorNumber];
bool fetched = false;
switch (cursorOp)
{
case blr_cursor_open:
if (request->req_operation == jrd_req::req_evaluate)
{
cursor->open(tdbb);
request->req_operation = jrd_req::req_return;
}
return parentStmt;
case blr_cursor_close:
if (request->req_operation == jrd_req::req_evaluate)
{
cursor->close(tdbb);
request->req_operation = jrd_req::req_return;
}
return parentStmt;
case blr_cursor_fetch:
case blr_cursor_fetch_scroll:
switch (request->req_operation)
{
case jrd_req::req_evaluate:
request->req_records_affected.clear();
if (cursorOp == blr_cursor_fetch)
fetched = cursor->fetchNext(tdbb);
else
{
fb_assert(cursorOp == blr_cursor_fetch_scroll);
const dsc* desc = EVL_expr(tdbb, request, scrollExpr);
const bool unknown = !desc || (request->req_flags & req_null);
const SINT64 offset = unknown ? 0 : MOV_get_int64(desc, 0);
switch (scrollOp)
{
case blr_scroll_forward:
fetched = cursor->fetchNext(tdbb);
break;
case blr_scroll_backward:
fetched = cursor->fetchPrior(tdbb);
break;
case blr_scroll_bof:
fetched = cursor->fetchFirst(tdbb);
break;
case blr_scroll_eof:
fetched = cursor->fetchLast(tdbb);
break;
case blr_scroll_absolute:
fetched = unknown ? false : cursor->fetchAbsolute(tdbb, offset);
break;
case blr_scroll_relative:
fetched = unknown ? false : cursor->fetchRelative(tdbb, offset);
break;
default:
fb_assert(false);
fetched = false;
}
}
if (fetched)
{
request->req_operation = jrd_req::req_evaluate;
return intoStmt;
}
request->req_operation = jrd_req::req_return;
default:
return parentStmt;
}
break;
}
fb_assert(false);
return NULL;
}
//--------------------
static RegisterNode<DeclareCursorNode> regDeclareCursorNode(blr_dcl_cursor);
DmlNode* DeclareCursorNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
DeclareCursorNode* node = FB_NEW(pool) DeclareCursorNode(pool);
node->cursorNumber = csb->csb_blr_reader.getWord();
node->rse = PAR_rse(tdbb, csb);
USHORT count = csb->csb_blr_reader.getWord();
node->refs = PAR_args(tdbb, csb, count, count);
return node;
}
DeclareCursorNode* DeclareCursorNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
fb_assert(dsqlCursorType != CUR_TYPE_NONE);
// Make sure the cursor doesn't exist.
PASS1_cursor_name(dsqlScratch, dsqlName, CUR_TYPE_ALL, false);
SelectExprNode* dt = FB_NEW(getPool()) SelectExprNode(getPool());
dt->dsqlFlags = RecordSourceNode::DFLAG_DERIVED | RecordSourceNode::DFLAG_CURSOR;
dt->querySpec = dsqlSelect->dsqlExpr;
dt->alias = dsqlName.c_str();
rse = PASS1_derived_table(dsqlScratch, dt, NULL, dsqlSelect->dsqlWithLock);
// Assign number and store in the dsqlScratch stack.
cursorNumber = dsqlScratch->cursorNumber++;
dsqlScratch->cursors.push(this);
dsqlScratch->putDebugCursor(cursorNumber, dsqlName);
++dsqlScratch->scopeLevel;
return this;
}
string DeclareCursorNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlCursorType);
NODE_PRINT(printer, dsqlScroll);
NODE_PRINT(printer, dsqlName);
NODE_PRINT(printer, dsqlSelect);
NODE_PRINT(printer, rse);
NODE_PRINT(printer, refs);
NODE_PRINT(printer, cursorNumber);
NODE_PRINT(printer, cursor);
return "DeclareCursorNode";
}
void DeclareCursorNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_dcl_cursor);
dsqlScratch->appendUShort(cursorNumber);
if (dsqlScroll)
dsqlScratch->appendUChar(blr_scrollable);
GEN_rse(dsqlScratch, rse);
ValueListNode* temp = rse->dsqlSelectList;
NestConst<ValueExprNode>* ptr = temp->items.begin();
NestConst<ValueExprNode>* end = temp->items.end();
fb_assert(temp->items.getCount() < MAX_USHORT);
dsqlScratch->appendUShort(temp->items.getCount());
while (ptr < end)
GEN_expr(dsqlScratch, *ptr++);
}
DeclareCursorNode* DeclareCursorNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, rse.getAddress());
doPass1(tdbb, csb, refs.getAddress());
return this;
}
DeclareCursorNode* DeclareCursorNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
rse->pass2Rse(tdbb, csb);
ExprNode::doPass2(tdbb, csb, rse.getAddress());
ExprNode::doPass2(tdbb, csb, refs.getAddress());
// Finish up processing of record selection expressions.
RecordSource* const rsb = CMP_post_rse(tdbb, csb, rse.getObject());
csb->csb_fors.add(rsb);
cursor = FB_NEW(*tdbb->getDefaultPool()) Cursor(csb, rsb, rse->rse_invariants,
(rse->flags & RseNode::FLAG_SCROLLABLE));
csb->csb_dbg_info->curIndexToName.get(cursorNumber, cursor->name);
if (cursorNumber >= csb->csb_cursors.getCount())
csb->csb_cursors.grow(cursorNumber + 1);
csb->csb_cursors[cursorNumber] = cursor;
StreamList cursorStreams;
cursor->getAccessPath()->findUsedStreams(cursorStreams);
// Activate cursor streams to allow index usage for <cursor>.<field> references, see CORE-4675.
// It's also useful for correlated sub-queries in the select list, see CORE-4379.
for (StreamList::const_iterator i = cursorStreams.begin(); i != cursorStreams.end(); ++i)
{
csb->csb_rpt[*i].csb_cursor_number = cursorNumber;
csb->csb_rpt[*i].activate();
}
return this;
}
const StmtNode* DeclareCursorNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
// Set up the cursors array...
if (cursorNumber >= request->req_cursors.getCount())
request->req_cursors.grow(cursorNumber + 1);
// And store cursor there.
request->req_cursors[cursorNumber] = cursor;
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<DeclareSubFuncNode> regDeclareSubFuncNode(blr_subfunc_decl);
DmlNode* DeclareSubFuncNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb,
const UCHAR /*blrOp*/)
{
MetaName name;
PAR_name(csb, name);
if (csb->csb_g_flags & csb_subroutine)
PAR_error(csb, Arg::Gds(isc_wish_list) << Arg::Gds(isc_random) << "nested sub function");
if (csb->subFunctions.exist(name))
PAR_error(csb, Arg::Gds(isc_random) << "duplicate sub function");
DeclareSubFuncNode* node = FB_NEW(pool) DeclareSubFuncNode(pool, name);
Function* subFunc = node->routine = FB_NEW(pool) Function(pool);
subFunc->setName(QualifiedName(name));
subFunc->setSubRoutine(true);
subFunc->setImplemented(true);
{ // scope
CompilerScratch* const subCsb = node->subCsb = CompilerScratch::newCsb(csb->csb_pool, 5);
subCsb->csb_g_flags |= csb_subroutine;
subCsb->csb_blr_reader = csb->csb_blr_reader;
BlrReader& reader = subCsb->csb_blr_reader;
ContextPoolHolder context(tdbb, &subCsb->csb_pool);
UCHAR type = reader.getByte();
if (type != SUB_ROUTINE_TYPE_PSQL)
PAR_syntax_error(csb, "sub function type");
UCHAR deterministic = reader.getByte();
if (deterministic != 0 && deterministic != 1)
PAR_syntax_error(csb, "sub function deterministic");
subFunc->fun_deterministic = deterministic == 1;
USHORT defaultCount = 0;
parseParameters(tdbb, pool, subCsb, subFunc->getInputFields(), &defaultCount);
subFunc->setDefaultCount(defaultCount);
parseParameters(tdbb, pool, subCsb, subFunc->getOutputFields());
subFunc->fun_inputs = subFunc->getInputFields().getCount();
node->blrLength = reader.getLong();
node->blrStart = reader.getPos();
subFunc->parseMessages(tdbb, subCsb, BlrReader(reader.getPos(), node->blrLength));
USHORT count = subFunc->getInputFormat() ? subFunc->getInputFormat()->fmt_count : 0;
if (subFunc->getInputFields().getCount() * 2 != count)
PAR_error(csb, Arg::Gds(isc_fun_param_mismatch) << name);
for (USHORT i = 0; i < count; i += 2u)
{
Parameter* parameter = subFunc->getInputFields()[i / 2u];
parameter->prm_desc = subFunc->getInputFormat()->fmt_desc[i];
}
Array<NestConst<Parameter> >& paramArray = subFunc->getOutputFields();
count = subFunc->getOutputFormat() ? subFunc->getOutputFormat()->fmt_count : 0;
if (count == 0 || paramArray.getCount() * 2 != count - 1u)
PAR_error(csb, Arg::Gds(isc_prc_out_param_mismatch) << name);
for (USHORT i = 0; i < count - 1u; i += 2u)
{
Parameter* parameter = paramArray[i / 2u];
parameter->prm_desc = subFunc->getOutputFormat()->fmt_desc[i];
}
DbgInfo* subDbgInfo = NULL;
if (csb->csb_dbg_info->subFuncs.get(name, subDbgInfo))
{
subCsb->csb_dbg_info = subDbgInfo;
csb->csb_dbg_info->subFuncs.remove(name);
}
}
csb->subFunctions.put(name, node);
csb->csb_blr_reader.setPos(node->blrStart + node->blrLength);
return node;
}
void DeclareSubFuncNode::parseParameters(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb,
Firebird::Array<NestConst<Parameter> >& paramArray, USHORT* defaultCount)
{
BlrReader& reader = csb->csb_blr_reader;
USHORT count = reader.getWord();
FB_SIZE_T pos = paramArray.getCount();
paramArray.resize(pos + count);
if (defaultCount)
*defaultCount = 0;
for (FB_SIZE_T i = 0; i < count; ++i)
{
Parameter* parameter = FB_NEW(pool) Parameter(pool);
parameter->prm_number = USHORT(i);
parameter->prm_fun_mechanism = FUN_value;
paramArray[pos + parameter->prm_number] = parameter;
PAR_name(csb, parameter->prm_name);
UCHAR hasDefault = reader.getByte();
if (hasDefault == 1)
{
if (defaultCount && *defaultCount == 0)
*defaultCount = paramArray.getCount() - i;
parameter->prm_default_value = PAR_parse_value(tdbb, csb);
}
else if (hasDefault != 0)
PAR_syntax_error(csb, "0 or 1");
}
}
string DeclareSubFuncNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, name);
NODE_PRINT(printer, dsqlDeterministic);
NODE_PRINT(printer, dsqlBlock);
return "DeclareSubFuncNode";
}
DeclareSubFuncNode* DeclareSubFuncNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
MemoryPool& pool = getPool();
if (dsqlScratch->flags & DsqlCompilerScratch::FLAG_SUB_ROUTINE)
ERR_post(Arg::Gds(isc_wish_list) << Arg::Gds(isc_random) << "nested sub function");
DsqlCompiledStatement* statement = FB_NEW(pool) DsqlCompiledStatement(pool);
if (dsqlScratch->clientDialect > SQL_DIALECT_V5)
statement->setBlrVersion(5);
else
statement->setBlrVersion(4);
statement->setSendMsg(FB_NEW(pool) dsql_msg(pool));
dsql_msg* message = FB_NEW(pool) dsql_msg(pool);
statement->setReceiveMsg(message);
message->msg_number = 1;
statement->setType(DsqlCompiledStatement::TYPE_SELECT);
blockScratch = FB_NEW(pool) DsqlCompilerScratch(pool,
dsqlScratch->getAttachment(), dsqlScratch->getTransaction(), statement);
blockScratch->clientDialect = dsqlScratch->clientDialect;
blockScratch->flags |= DsqlCompilerScratch::FLAG_FUNCTION | DsqlCompilerScratch::FLAG_SUB_ROUTINE;
blockScratch->flags |= dsqlScratch->flags & DsqlCompilerScratch::FLAG_DDL;
dsqlBlock = dsqlBlock->dsqlPass(blockScratch);
dsqlFunction = FB_NEW(pool) dsql_udf(pool);
dsqlFunction->udf_flags = UDF_subfunc;
dsqlFunction->udf_name.identifier = name;
fb_assert(dsqlBlock->returns.getCount() == 1);
const TypeClause* returnType = dsqlBlock->returns[0]->type;
dsqlFunction->udf_dtype = returnType->dtype;
dsqlFunction->udf_scale = returnType->scale;
dsqlFunction->udf_sub_type = returnType->subType;
dsqlFunction->udf_length = returnType->length;
dsqlFunction->udf_character_set_id = returnType->charSetId;
const Array<NestConst<ParameterClause> >& paramArray = dsqlBlock->parameters;
bool defaultFound = false;
for (const NestConst<ParameterClause>* i = paramArray.begin(); i != paramArray.end(); ++i)
{
// ASF: dsqlFunction->udf_arguments is only checked for its count for now.
dsqlFunction->udf_arguments.add(dsc());
const ParameterClause* param = *i;
if (param->defaultClause)
{
defaultFound = true;
if (dsqlFunction->udf_def_count == 0)
dsqlFunction->udf_def_count = paramArray.end() - i;
}
else if (defaultFound)
{
// Parameter without default value after parameters with default.
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-204) <<
Arg::Gds(isc_bad_default_value) <<
Arg::Gds(isc_invalid_clause) << Arg::Str("defaults must be last"));
}
}
dsqlScratch->putSubFunction(dsqlFunction);
return this;
}
void DeclareSubFuncNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
GEN_request(blockScratch, dsqlBlock);
dsqlScratch->appendUChar(blr_subfunc_decl);
dsqlScratch->appendNullString(name.c_str());
dsqlScratch->appendUChar(SUB_ROUTINE_TYPE_PSQL);
dsqlScratch->appendUChar(dsqlDeterministic ? 1 : 0);
genParameters(dsqlScratch, dsqlBlock->parameters);
genParameters(dsqlScratch, dsqlBlock->returns);
BlrDebugWriter::BlrData& blrData = blockScratch->getBlrData();
dsqlScratch->appendULong(ULONG(blrData.getCount()));
dsqlScratch->appendBytes(blrData.begin(), blrData.getCount());
dsqlScratch->putDebugSubFunction(this);
}
void DeclareSubFuncNode::genParameters(DsqlCompilerScratch* dsqlScratch,
Array<NestConst<ParameterClause> >& paramArray)
{
dsqlScratch->appendUShort(USHORT(paramArray.getCount()));
for (NestConst<ParameterClause>* i = paramArray.begin(); i != paramArray.end(); ++i)
{
ParameterClause* param = *i;
dsqlScratch->appendNullString(param->name.c_str());
if (param->defaultClause)
{
dsqlScratch->appendUChar(1);
GEN_expr(dsqlScratch, param->defaultClause->value);
}
else
dsqlScratch->appendUChar(0);
}
}
DeclareSubFuncNode* DeclareSubFuncNode::pass1(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
DeclareSubFuncNode* DeclareSubFuncNode::pass2(thread_db* tdbb, CompilerScratch* /*csb*/)
{
// scope needed here?
{ // scope
ContextPoolHolder context(tdbb, &subCsb->csb_pool);
PAR_blr(tdbb, NULL, blrStart, blrLength, NULL, &subCsb, NULL, false, 0);
}
return this;
}
const StmtNode* DeclareSubFuncNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
// Nothing to execute. This is the declaration node.
if (request->req_operation == jrd_req::req_evaluate)
request->req_operation = jrd_req::req_return;
return parentStmt;
}
//--------------------
static RegisterNode<DeclareSubProcNode> regDeclareSubProcNode(blr_subproc_decl);
DmlNode* DeclareSubProcNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
MetaName name;
PAR_name(csb, name);
if (csb->csb_g_flags & csb_subroutine)
PAR_error(csb, Arg::Gds(isc_wish_list) << Arg::Gds(isc_random) << "nested sub procedure");
if (csb->subProcedures.exist(name))
PAR_error(csb, Arg::Gds(isc_random) << "duplicate sub procedure");
DeclareSubProcNode* node = FB_NEW(pool) DeclareSubProcNode(pool, name);
jrd_prc* subProc = node->routine = FB_NEW(pool) jrd_prc(pool);
subProc->setName(QualifiedName(name));
subProc->setSubRoutine(true);
subProc->setImplemented(true);
{ // scope
CompilerScratch* const subCsb = node->subCsb = CompilerScratch::newCsb(csb->csb_pool, 5);
subCsb->csb_g_flags |= csb_subroutine;
subCsb->csb_blr_reader = csb->csb_blr_reader;
BlrReader& reader = subCsb->csb_blr_reader;
ContextPoolHolder context(tdbb, &subCsb->csb_pool);
UCHAR type = reader.getByte();
if (type != SUB_ROUTINE_TYPE_PSQL)
PAR_syntax_error(csb, "sub routine type");
type = reader.getByte();
if (type != 0 && type != 1)
PAR_syntax_error(csb, "sub procedure type");
subProc->prc_type = type == 1 ? prc_selectable : prc_executable;
USHORT defaultCount = 0;
parseParameters(tdbb, pool, subCsb, subProc->getInputFields(), &defaultCount);
subProc->setDefaultCount(defaultCount);
parseParameters(tdbb, pool, subCsb, subProc->getOutputFields());
node->blrLength = reader.getLong();
node->blrStart = reader.getPos();
subProc->parseMessages(tdbb, subCsb, BlrReader(reader.getPos(), node->blrLength));
USHORT count = subProc->getInputFormat() ? subProc->getInputFormat()->fmt_count : 0;
if (subProc->getInputFields().getCount() * 2 != count)
PAR_error(csb, Arg::Gds(isc_prcmismat) << name);
for (USHORT i = 0; i < count; i += 2u)
{
Parameter* parameter = subProc->getInputFields()[i / 2u];
parameter->prm_desc = subProc->getInputFormat()->fmt_desc[i];
}
Array<NestConst<Parameter> >& paramArray = subProc->getOutputFields();
count = subProc->getOutputFormat() ? subProc->getOutputFormat()->fmt_count : 0;
if (count == 0 || paramArray.getCount() * 2 != count - 1u)
PAR_error(csb, Arg::Gds(isc_prc_out_param_mismatch) << name);
Format* format = Format::newFormat(pool, paramArray.getCount());
subProc->prc_record_format = format;
format->fmt_length = FLAG_BYTES(format->fmt_count);
for (USHORT i = 0; i < count - 1u; i += 2u)
{
Parameter* parameter = paramArray[i / 2u];
parameter->prm_desc = subProc->getOutputFormat()->fmt_desc[i];
dsc& fmtDesc = format->fmt_desc[i / 2u];
fmtDesc = parameter->prm_desc;
if (fmtDesc.dsc_dtype >= dtype_aligned)
format->fmt_length = FB_ALIGN(format->fmt_length, type_alignments[fmtDesc.dsc_dtype]);
fmtDesc.dsc_address = (UCHAR*)(IPTR) format->fmt_length;
format->fmt_length += fmtDesc.dsc_length;
}
DbgInfo* subDbgInfo = NULL;
if (csb->csb_dbg_info->subProcs.get(name, subDbgInfo))
{
subCsb->csb_dbg_info = subDbgInfo;
csb->csb_dbg_info->subProcs.remove(name);
}
}
csb->subProcedures.put(name, node);
csb->csb_blr_reader.setPos(node->blrStart + node->blrLength);
return node;
}
void DeclareSubProcNode::parseParameters(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb,
Array<NestConst<Parameter> >& paramArray, USHORT* defaultCount)
{
BlrReader& reader = csb->csb_blr_reader;
paramArray.resize(reader.getWord());
if (defaultCount)
*defaultCount = 0;
for (FB_SIZE_T i = 0; i < paramArray.getCount(); ++i)
{
Parameter* parameter = FB_NEW(pool) Parameter(pool);
parameter->prm_number = USHORT(i);
paramArray[parameter->prm_number] = parameter;
PAR_name(csb, parameter->prm_name);
UCHAR hasDefault = reader.getByte();
if (hasDefault == 1)
{
if (defaultCount && *defaultCount == 0)
*defaultCount = paramArray.getCount() - i;
parameter->prm_default_value = PAR_parse_value(tdbb, csb);
}
else if (hasDefault != 0)
PAR_syntax_error(csb, "0 or 1");
}
}
string DeclareSubProcNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, name);
NODE_PRINT(printer, dsqlBlock);
return "DeclareSubProcNode";
}
DeclareSubProcNode* DeclareSubProcNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
MemoryPool& pool = getPool();
if (dsqlScratch->flags & DsqlCompilerScratch::FLAG_SUB_ROUTINE)
ERR_post(Arg::Gds(isc_wish_list) << Arg::Gds(isc_random) << "nested sub procedure");
DsqlCompiledStatement* statement = FB_NEW(pool) DsqlCompiledStatement(pool);
if (dsqlScratch->clientDialect > SQL_DIALECT_V5)
statement->setBlrVersion(5);
else
statement->setBlrVersion(4);
statement->setSendMsg(FB_NEW(pool) dsql_msg(pool));
dsql_msg* message = FB_NEW(pool) dsql_msg(pool);
statement->setReceiveMsg(message);
message->msg_number = 1;
statement->setType(DsqlCompiledStatement::TYPE_SELECT);
blockScratch = FB_NEW(pool) DsqlCompilerScratch(pool,
dsqlScratch->getAttachment(), dsqlScratch->getTransaction(), statement);
blockScratch->clientDialect = dsqlScratch->clientDialect;
blockScratch->flags |= DsqlCompilerScratch::FLAG_PROCEDURE | DsqlCompilerScratch::FLAG_SUB_ROUTINE;
blockScratch->flags |= dsqlScratch->flags & DsqlCompilerScratch::FLAG_DDL;
dsqlBlock = dsqlBlock->dsqlPass(blockScratch);
dsqlProcedure = FB_NEW(pool) dsql_prc(pool);
dsqlProcedure->prc_flags = PRC_subproc;
dsqlProcedure->prc_name.identifier = name;
dsqlProcedure->prc_in_count = USHORT(dsqlBlock->parameters.getCount());
dsqlProcedure->prc_out_count = USHORT(dsqlBlock->returns.getCount());
if (dsqlBlock->parameters.hasData())
{
Array<NestConst<ParameterClause> >& paramArray = dsqlBlock->parameters;
dsqlProcedure->prc_inputs = paramArray.front()->type;
for (const NestConst<ParameterClause>* i = paramArray.begin(); i != paramArray.end(); ++i)
{
const ParameterClause* param = *i;
if (param->defaultClause)
{
if (dsqlProcedure->prc_def_count == 0)
dsqlProcedure->prc_def_count = paramArray.end() - i;
}
else if (dsqlProcedure->prc_def_count != 0)
{
// Parameter without default value after parameters with default.
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-204) <<
Arg::Gds(isc_bad_default_value) <<
Arg::Gds(isc_invalid_clause) << Arg::Str("defaults must be last"));
}
}
}
if (dsqlBlock->returns.hasData())
dsqlProcedure->prc_outputs = dsqlBlock->returns.front()->type;
dsqlScratch->putSubProcedure(dsqlProcedure);
return this;
}
void DeclareSubProcNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
GEN_request(blockScratch, dsqlBlock);
dsqlScratch->appendUChar(blr_subproc_decl);
dsqlScratch->appendNullString(name.c_str());
dsqlScratch->appendUChar(SUB_ROUTINE_TYPE_PSQL);
dsqlScratch->appendUChar(
blockScratch->getStatement()->getFlags() & DsqlCompiledStatement::FLAG_SELECTABLE ? 1 : 0);
genParameters(dsqlScratch, dsqlBlock->parameters);
genParameters(dsqlScratch, dsqlBlock->returns);
BlrDebugWriter::BlrData& blrData = blockScratch->getBlrData();
dsqlScratch->appendULong(ULONG(blrData.getCount()));
dsqlScratch->appendBytes(blrData.begin(), blrData.getCount());
dsqlScratch->putDebugSubProcedure(this);
}
void DeclareSubProcNode::genParameters(DsqlCompilerScratch* dsqlScratch,
Array<NestConst<ParameterClause> >& paramArray)
{
dsqlScratch->appendUShort(USHORT(paramArray.getCount()));
for (NestConst<ParameterClause>* i = paramArray.begin(); i != paramArray.end(); ++i)
{
ParameterClause* param = *i;
dsqlScratch->appendNullString(param->name.c_str());
if (param->defaultClause)
{
dsqlScratch->appendUChar(1);
GEN_expr(dsqlScratch, param->defaultClause->value);
}
else
dsqlScratch->appendUChar(0);
}
}
DeclareSubProcNode* DeclareSubProcNode::pass1(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
DeclareSubProcNode* DeclareSubProcNode::pass2(thread_db* tdbb, CompilerScratch* /*csb*/)
{
ContextPoolHolder context(tdbb, &subCsb->csb_pool);
PAR_blr(tdbb, NULL, blrStart, blrLength, NULL, &subCsb, NULL, false, 0);
return this;
}
const StmtNode* DeclareSubProcNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
// Nothing to execute. This is the declaration node.
if (request->req_operation == jrd_req::req_evaluate)
request->req_operation = jrd_req::req_return;
return parentStmt;
}
//--------------------
static RegisterNode<DeclareVariableNode> regDeclareVariableNode(blr_dcl_variable);
DmlNode* DeclareVariableNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
DeclareVariableNode* node = FB_NEW(pool) DeclareVariableNode(pool);
node->varId = csb->csb_blr_reader.getWord();
ItemInfo itemInfo;
PAR_desc(tdbb, csb, &node->varDesc, &itemInfo);
csb->csb_variables = vec<DeclareVariableNode*>::newVector(
*tdbb->getDefaultPool(), csb->csb_variables, node->varId + 1);
if (itemInfo.isSpecial())
{
csb->csb_dbg_info->varIndexToName.get(node->varId, itemInfo.name);
csb->csb_map_item_info.put(Item(Item::TYPE_VARIABLE, node->varId), itemInfo);
}
if (itemInfo.explicitCollation)
{
CompilerScratch::Dependency dependency(obj_collation);
dependency.number = INTL_TEXT_TYPE(node->varDesc);
csb->csb_dependencies.push(dependency);
}
return node;
}
DeclareVariableNode* DeclareVariableNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string DeclareVariableNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlDef);
NODE_PRINT(printer, varId);
NODE_PRINT(printer, varDesc);
return "DeclareVariableNode";
}
void DeclareVariableNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
DeclareVariableNode* DeclareVariableNode::copy(thread_db* tdbb, NodeCopier& copier) const
{
DeclareVariableNode* node = FB_NEW(*tdbb->getDefaultPool()) DeclareVariableNode(*tdbb->getDefaultPool());
node->varId = varId + copier.csb->csb_remap_variable;
node->varDesc = varDesc;
copier.csb->csb_variables = vec<DeclareVariableNode*>::newVector(*tdbb->getDefaultPool(),
copier.csb->csb_variables, node->varId + 1);
return node;
}
DeclareVariableNode* DeclareVariableNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
vec<DeclareVariableNode*>* vector = csb->csb_variables = vec<DeclareVariableNode*>::newVector(
*tdbb->getDefaultPool(), csb->csb_variables, varId + 1);
fb_assert(!(*vector)[varId]);
(*vector)[varId] = this;
return this;
}
DeclareVariableNode* DeclareVariableNode::pass2(thread_db* /*tdbb*/, CompilerScratch* csb)
{
impureOffset = CMP_impure(csb, sizeof(impure_value));
return this;
}
const StmtNode* DeclareVariableNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
impure_value* variable = request->getImpure<impure_value>(impureOffset);
variable->vlu_desc = varDesc;
variable->vlu_desc.dsc_flags = 0;
if (variable->vlu_desc.dsc_dtype <= dtype_varying)
{
if (!variable->vlu_string)
{
const USHORT len = variable->vlu_desc.dsc_length;
variable->vlu_string = FB_NEW_RPT(*tdbb->getDefaultPool(), len) VaryingString();
variable->vlu_string->str_length = len;
}
variable->vlu_desc.dsc_address = variable->vlu_string->str_data;
}
else
variable->vlu_desc.dsc_address = (UCHAR*) &variable->vlu_misc;
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<EraseNode> regEraseNode(blr_erase);
DmlNode* EraseNode::parse(thread_db* /*tdbb*/, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
const USHORT n = csb->csb_blr_reader.getByte();
if (n >= csb->csb_rpt.getCount() || !(csb->csb_rpt[n].csb_flags & csb_used))
PAR_error(csb, Arg::Gds(isc_ctxnotdef));
EraseNode* node = FB_NEW(pool) EraseNode(pool);
node->stream = csb->csb_rpt[n].csb_stream;
return node;
}
StmtNode* EraseNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
thread_db* tdbb = JRD_get_thread_data(); //necessary?
NestConst<RelationSourceNode> relation = dsqlRelation;
EraseNode* node = FB_NEW(getPool()) EraseNode(getPool());
if (dsqlCursorName.hasData() && dsqlScratch->isPsql())
{
node->dsqlContext = dsqlPassCursorContext(dsqlScratch, dsqlCursorName, relation);
// Process old context values.
dsqlScratch->context->push(node->dsqlContext);
++dsqlScratch->scopeLevel;
node->statement = dsqlProcessReturning(dsqlScratch, dsqlReturning, statement);
--dsqlScratch->scopeLevel;
dsqlScratch->context->pop();
return SavepointEncloseNode::make(getPool(), dsqlScratch, node);
}
dsqlScratch->getStatement()->setType(dsqlCursorName.hasData() ?
DsqlCompiledStatement::TYPE_DELETE_CURSOR : DsqlCompiledStatement::TYPE_DELETE);
// Generate record selection expression.
RseNode* rse;
if (dsqlCursorName.hasData())
rse = dsqlPassCursorReference(dsqlScratch, dsqlCursorName, relation);
else
{
rse = FB_NEW(getPool()) RseNode(getPool());
rse->dsqlStreams = FB_NEW(getPool()) RecSourceListNode(getPool(), 1);
doDsqlPass(dsqlScratch, rse->dsqlStreams->items[0], relation, false);
if (dsqlBoolean)
rse->dsqlWhere = doDsqlPass(dsqlScratch, dsqlBoolean, false);
if (dsqlPlan)
rse->rse_plan = doDsqlPass(dsqlScratch, dsqlPlan, false);
if (dsqlOrder)
rse->dsqlOrder = PASS1_sort(dsqlScratch, dsqlOrder, NULL);
if (dsqlRows)
PASS1_limit(dsqlScratch, dsqlRows->length, dsqlRows->skip, rse);
}
if (dsqlReturning || statement)
rse->dsqlFlags |= RecordSourceNode::DFLAG_SINGLETON;
node->dsqlRse = rse;
node->dsqlRelation = rse->dsqlStreams->items[0]->as<RelationSourceNode>();
node->statement = dsqlProcessReturning(dsqlScratch, dsqlReturning, statement);
StmtNode* ret = dsqlNullifyReturning(dsqlScratch, node, true);
dsqlScratch->context->pop();
return SavepointEncloseNode::make(getPool(), dsqlScratch, ret);
}
string EraseNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlRelation);
NODE_PRINT(printer, dsqlBoolean);
NODE_PRINT(printer, dsqlPlan);
NODE_PRINT(printer, dsqlOrder);
NODE_PRINT(printer, dsqlRows);
NODE_PRINT(printer, dsqlCursorName);
NODE_PRINT(printer, dsqlReturning);
NODE_PRINT(printer, dsqlRse);
NODE_PRINT(printer, dsqlContext);
NODE_PRINT(printer, statement);
NODE_PRINT(printer, subStatement);
NODE_PRINT(printer, stream);
return "EraseNode";
}
void EraseNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
const dsql_msg* message = dsqlGenDmlHeader(dsqlScratch, dsqlRse);
const dsql_ctx* context;
if (dsqlContext)
{
context = dsqlContext;
if (statement)
{
dsqlScratch->appendUChar(blr_begin);
statement->genBlr(dsqlScratch);
dsqlScratch->appendUChar(blr_erase);
GEN_stuff_context(dsqlScratch, context);
dsqlScratch->appendUChar(blr_end);
}
else
{
dsqlScratch->appendUChar(blr_erase);
GEN_stuff_context(dsqlScratch, context);
}
}
else
{
context = dsqlRelation->dsqlContext;
if (statement)
{
dsqlScratch->appendUChar(blr_begin);
statement->genBlr(dsqlScratch);
dsqlScratch->appendUChar(blr_erase);
GEN_stuff_context(dsqlScratch, context);
dsqlScratch->appendUChar(blr_end);
}
else
{
dsqlScratch->appendUChar(blr_erase);
GEN_stuff_context(dsqlScratch, context);
}
}
if (message)
dsqlScratch->appendUChar(blr_end);
}
EraseNode* EraseNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
pass1Erase(tdbb, csb, this);
doPass1(tdbb, csb, statement.getAddress());
doPass1(tdbb, csb, subStatement.getAddress());
return this;
}
// Checkout an erase statement. If it references a view, and is kosher, fix it up.
void EraseNode::pass1Erase(thread_db* tdbb, CompilerScratch* csb, EraseNode* node)
{
// If updateable views with triggers are involved, there maybe a recursive call to be ignored.
if (node->subStatement)
return;
// To support nested views, loop until we hit a table or a view with user-defined triggers
// (which means no update).
jrd_rel* parent = NULL;
jrd_rel* view = NULL;
StreamType parentStream;
for (;;)
{
StreamType newStream = node->stream;
const StreamType stream = newStream;
CompilerScratch::csb_repeat* const tail = &csb->csb_rpt[stream];
tail->csb_flags |= csb_erase;
jrd_rel* const relation = tail->csb_relation;
view = relation->rel_view_rse ? relation : view;
if (!parent)
{
parent = tail->csb_view;
parentStream = tail->csb_view_stream;
}
postTriggerAccess(csb, relation, ExternalAccess::exa_delete, view);
// Check out delete. If this is a delete thru a view, verify the view by checking for read
// access on the base table. If field-level select privileges are implemented, this needs
// to be enhanced.
SecurityClass::flags_t priv = SCL_delete;
if (parent)
priv |= SCL_select;
const trig_vec* trigger = relation->rel_pre_erase ?
relation->rel_pre_erase : relation->rel_post_erase;
// If we have a view with triggers, let's expand it.
if (relation->rel_view_rse && trigger)
{
newStream = csb->nextStream();
node->stream = newStream;
CMP_csb_element(csb, newStream)->csb_relation = relation;
node->statement = pass1ExpandView(tdbb, csb, stream, newStream, false);
}
// Get the source relation, either a table or yet another view.
RelationSourceNode* source = pass1Update(tdbb, csb, relation, trigger, stream, newStream,
priv, parent, parentStream, parentStream);
if (!source)
return; // no source means we're done
parent = relation;
parentStream = stream;
// Remap the source stream.
StreamType* map = tail->csb_map;
if (trigger)
{
// ASF: This code is responsible to make view's WITH CHECK OPTION to work as constraints.
// I don't see how it could run for delete statements under normal conditions.
// Set up the new target stream.
EraseNode* viewNode = FB_NEW(*tdbb->getDefaultPool()) EraseNode(*tdbb->getDefaultPool());
viewNode->stream = node->stream;
node->subStatement = viewNode;
// Substitute the original delete node with the newly created one.
node = viewNode;
}
else
{
// This relation is not actually being updated as this operation
// goes deeper (we have a naturally updatable view).
csb->csb_rpt[newStream].csb_flags &= ~csb_view_update;
}
// Let's reset the target stream.
newStream = source->getStream();
node->stream = map[newStream];
}
}
EraseNode* EraseNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, statement.getAddress(), this);
doPass2(tdbb, csb, subStatement.getAddress(), this);
impureOffset = CMP_impure(csb, sizeof(SLONG));
csb->csb_rpt[stream].csb_flags |= csb_update;
return this;
}
const StmtNode* EraseNode::execute(thread_db* tdbb, jrd_req* request, ExeState* exeState) const
{
const StmtNode* retNode;
if (request->req_operation == jrd_req::req_unwind)
retNode = parentStmt;
else if (request->req_operation == jrd_req::req_return && subStatement)
{
if (!exeState->topNode)
{
exeState->topNode = this;
exeState->whichEraseTrig = PRE_TRIG;
}
exeState->prevNode = this;
retNode = erase(tdbb, request, exeState->whichEraseTrig);
if (exeState->whichEraseTrig == PRE_TRIG)
{
retNode = subStatement;
fb_assert(retNode->parentStmt == this);
///retNode->parentStmt = exeState->prevNode;
}
if (exeState->topNode == this && exeState->whichEraseTrig == POST_TRIG)
{
exeState->topNode = NULL;
exeState->whichEraseTrig = ALL_TRIGS;
}
else
request->req_operation = jrd_req::req_evaluate;
}
else
{
exeState->prevNode = this;
retNode = erase(tdbb, request, ALL_TRIGS);
if (!subStatement && exeState->whichEraseTrig == PRE_TRIG)
exeState->whichEraseTrig = POST_TRIG;
}
return retNode;
}
// Perform erase operation.
const StmtNode* EraseNode::erase(thread_db* tdbb, jrd_req* request, WhichTrigger whichTrig) const
{
Jrd::Attachment* attachment = tdbb->getAttachment();
jrd_tra* transaction = request->req_transaction;
record_param* rpb = &request->req_rpb[stream];
jrd_rel* relation = rpb->rpb_relation;
if (rpb->rpb_number.isBof() || (!relation->rel_view_rse && !rpb->rpb_number.isValid()))
ERR_post(Arg::Gds(isc_no_cur_rec));
switch (request->req_operation)
{
case jrd_req::req_evaluate:
{
request->req_records_affected.bumpModified(false);
if (!statement)
break;
const Format* format = MET_current(tdbb, rpb->rpb_relation);
Record* record = VIO_record(tdbb, rpb, format, tdbb->getDefaultPool());
rpb->rpb_address = record->getData();
rpb->rpb_length = format->fmt_length;
rpb->rpb_format_number = format->fmt_version;
return statement;
}
case jrd_req::req_return:
break;
default:
return parentStmt;
}
request->req_operation = jrd_req::req_return;
RLCK_reserve_relation(tdbb, transaction, relation, true);
// If the stream was sorted, the various fields in the rpb are probably junk.
// Just to make sure that everything is cool, refetch and release the record.
if (rpb->rpb_runtime_flags & RPB_refetch)
{
VIO_refetch_record(tdbb, rpb, transaction, false);
rpb->rpb_runtime_flags &= ~RPB_refetch;
}
if (transaction != attachment->getSysTransaction())
++transaction->tra_save_point->sav_verb_count;
// Handle pre-operation trigger.
preModifyEraseTriggers(tdbb, &relation->rel_pre_erase, whichTrig, rpb, NULL, TRIGGER_DELETE);
if (relation->rel_file)
EXT_erase(rpb, transaction);
else if (relation->isVirtual())
VirtualTable::erase(tdbb, rpb);
else if (!relation->rel_view_rse)
VIO_erase(tdbb, rpb, transaction);
// Handle post operation trigger.
if (relation->rel_post_erase && whichTrig != PRE_TRIG)
{
EXE_execute_triggers(tdbb, &relation->rel_post_erase, rpb, NULL, TRIGGER_DELETE, POST_TRIG);
}
// Call IDX_erase (which checks constraints) after all post erase triggers have fired.
// This is required for cascading referential integrity, which can be implemented as
// post_erase triggers.
if (!relation->rel_file && !relation->rel_view_rse && !relation->isVirtual())
IDX_erase(tdbb, rpb, transaction);
// CVC: Increment the counter only if we called VIO/EXT_erase() and we were successful.
if (!(request->req_view_flags & req_first_erase_return))
{
request->req_view_flags |= req_first_erase_return;
if (relation->rel_view_rse)
request->req_top_view_erase = relation;
}
if (relation == request->req_top_view_erase)
{
if (whichTrig == ALL_TRIGS || whichTrig == POST_TRIG)
{
request->req_records_deleted++;
request->req_records_affected.bumpModified(true);
}
}
else if (relation->rel_file || !relation->rel_view_rse)
{
request->req_records_deleted++;
request->req_records_affected.bumpModified(true);
}
if (transaction != attachment->getSysTransaction())
--transaction->tra_save_point->sav_verb_count;
rpb->rpb_number.setValid(false);
return parentStmt;
}
//--------------------
static RegisterNode<ErrorHandlerNode> regErrorHandlerNode(blr_error_handler);
DmlNode* ErrorHandlerNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
ErrorHandlerNode* node = FB_NEW(pool) ErrorHandlerNode(pool);
const USHORT n = csb->csb_blr_reader.getWord();
for (unsigned i = 0; i < n; i++)
{
const USHORT codeType = csb->csb_blr_reader.getByte();
ExceptionItem& item = node->conditions.add();
switch (codeType)
{
case blr_sql_code:
item.type = ExceptionItem::SQL_CODE;
item.code = (SSHORT) csb->csb_blr_reader.getWord();
break;
case blr_sql_state:
item.type = ExceptionItem::SQL_STATE;
PAR_name(csb, item.name);
break;
case blr_gds_code:
item.type = ExceptionItem::GDS_CODE;
PAR_name(csb, item.name);
item.name.lower();
if (!(item.code = PAR_symbol_to_gdscode(item.name)))
PAR_error(csb, Arg::Gds(isc_codnotdef) << item.name);
break;
case blr_exception:
{
PAR_name(csb, item.name);
if (!MET_load_exception(tdbb, item))
PAR_error(csb, Arg::Gds(isc_xcpnotdef) << item.name);
CompilerScratch::Dependency dependency(obj_exception);
dependency.number = item.code;
csb->csb_dependencies.push(dependency);
break;
}
case blr_default_code:
item.type = ExceptionItem::XCP_DEFAULT;
item.code = 0;
break;
default:
fb_assert(FALSE);
break;
}
}
node->action = PAR_parse_stmt(tdbb, csb);
return node;
}
ErrorHandlerNode* ErrorHandlerNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
ErrorHandlerNode* node = FB_NEW(getPool()) ErrorHandlerNode(getPool());
node->conditions = conditions;
node->action = action->dsqlPass(dsqlScratch);
return node;
}
string ErrorHandlerNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, action);
NODE_PRINT(printer, conditions);
return "ErrorHandlerNode";
}
void ErrorHandlerNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_error_handler);
fb_assert(conditions.getCount() < MAX_USHORT);
dsqlScratch->appendUShort(USHORT(conditions.getCount()));
for (ExceptionArray::iterator i = conditions.begin(); i != conditions.end(); ++i)
{
switch (i->type)
{
case ExceptionItem::SQL_CODE:
dsqlScratch->appendUChar(blr_sql_code);
dsqlScratch->appendUShort(i->code);
break;
case ExceptionItem::SQL_STATE:
dsqlScratch->appendUChar(blr_sql_state);
dsqlScratch->appendNullString(i->name.c_str());
break;
case ExceptionItem::GDS_CODE:
dsqlScratch->appendUChar(blr_gds_code);
dsqlScratch->appendNullString(i->name.c_str());
break;
case ExceptionItem::XCP_CODE:
dsqlScratch->appendUChar(blr_exception);
dsqlScratch->appendNullString(i->name.c_str());
break;
case ExceptionItem::XCP_DEFAULT:
dsqlScratch->appendUChar(blr_default_code);
break;
default:
fb_assert(false);
break;
}
}
action->genBlr(dsqlScratch);
}
ErrorHandlerNode* ErrorHandlerNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, action.getAddress());
return this;
}
ErrorHandlerNode* ErrorHandlerNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, action.getAddress(), this);
return this;
}
const StmtNode* ErrorHandlerNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* exeState) const
{
if ((request->req_flags & req_error_handler) && !exeState->errorPending)
{
fb_assert(request->req_caller == exeState->oldRequest);
request->req_caller = NULL;
exeState->exit = true;
return this;
}
const StmtNode* retNode = parentStmt;
retNode = retNode->parentStmt;
if (request->req_operation == jrd_req::req_unwind)
retNode = retNode->parentStmt;
request->req_last_xcp.clear();
return retNode;
}
//--------------------
static RegisterNode<ExecProcedureNode> regExecProcedureNodeProc(blr_exec_proc);
static RegisterNode<ExecProcedureNode> regExecProcedureNodeProc2(blr_exec_proc2);
static RegisterNode<ExecProcedureNode> regExecProcedureNodePid(blr_exec_pid);
static RegisterNode<ExecProcedureNode> regExecProcedureNodeSubProc(blr_exec_subproc);
// Parse an execute procedure reference.
DmlNode* ExecProcedureNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
SET_TDBB(tdbb);
jrd_prc* procedure = NULL;
QualifiedName name;
if (blrOp == blr_exec_pid)
{
const USHORT pid = csb->csb_blr_reader.getWord();
if (!(procedure = MET_lookup_procedure_id(tdbb, pid, false, false, 0)))
name.identifier.printf("id %d", pid);
}
else
{
if (blrOp == blr_exec_proc2)
PAR_name(csb, name.package);
PAR_name(csb, name.identifier);
if (blrOp == blr_exec_subproc)
{
DeclareSubProcNode* declareNode;
if (csb->subProcedures.get(name.identifier, declareNode))
procedure = declareNode->routine;
}
else
procedure = MET_lookup_procedure(tdbb, name, false);
}
if (!procedure)
PAR_error(csb, Arg::Gds(isc_prcnotdef) << Arg::Str(name.toString()));
ExecProcedureNode* node = FB_NEW(pool) ExecProcedureNode(pool);
node->procedure = procedure;
PAR_procedure_parms(tdbb, csb, procedure, node->inputMessage.getAddress(),
node->inputSources.getAddress(), node->inputTargets.getAddress(), true);
PAR_procedure_parms(tdbb, csb, procedure, node->outputMessage.getAddress(),
node->outputSources.getAddress(), node->outputTargets.getAddress(), false);
if (!procedure->isSubRoutine())
{
CompilerScratch::Dependency dependency(obj_procedure);
dependency.procedure = procedure;
csb->csb_dependencies.push(dependency);
}
return node;
}
ExecProcedureNode* ExecProcedureNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
dsql_prc* procedure = NULL;
if (dsqlName.package.isEmpty())
procedure = dsqlScratch->getSubProcedure(dsqlName.identifier);
if (!procedure)
procedure = METD_get_procedure(dsqlScratch->getTransaction(), dsqlScratch, dsqlName);
if (!procedure)
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-204) <<
Arg::Gds(isc_dsql_procedure_err) <<
Arg::Gds(isc_random) <<
Arg::Str(dsqlName.toString()));
}
if (!dsqlScratch->isPsql())
{
dsqlScratch->procedure = procedure;
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_EXEC_PROCEDURE);
}
ExecProcedureNode* node = FB_NEW(getPool()) ExecProcedureNode(getPool(), dsqlName);
node->dsqlProcedure = procedure;
if (node->dsqlName.package.isEmpty() && procedure->prc_name.package.hasData())
node->dsqlName.package = procedure->prc_name.package;
// Handle input parameters.
const USHORT count = inputSources ? inputSources->items.getCount() : 0;
if (count > procedure->prc_in_count || count < procedure->prc_in_count - procedure->prc_def_count)
ERRD_post(Arg::Gds(isc_prcmismat) << Arg::Str(dsqlName.toString()));
node->inputSources = doDsqlPass(dsqlScratch, inputSources);
if (count)
{
// Initialize this stack variable, and make it look like a node.
dsc desc_node;
NestConst<ValueExprNode>* ptr = node->inputSources->items.begin();
const NestConst<ValueExprNode>* end = node->inputSources->items.end();
for (const dsql_fld* field = procedure->prc_inputs; ptr != end; ++ptr, field = field->fld_next)
{
DEV_BLKCHK(field, dsql_type_fld);
DEV_BLKCHK(*ptr, dsql_type_nod);
MAKE_desc_from_field(&desc_node, field);
PASS1_set_parameter_type(dsqlScratch, *ptr, &desc_node, false);
}
}
// Handle output parameters.
if (dsqlScratch->isPsql())
{
const USHORT outCount = outputSources ? outputSources->items.getCount() : 0;
if (outCount != procedure->prc_out_count)
ERRD_post(Arg::Gds(isc_prc_out_param_mismatch) << Arg::Str(dsqlName.toString()));
node->outputSources = dsqlPassArray(dsqlScratch, outputSources);
}
else
{
if (outputSources)
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
// Token unknown
Arg::Gds(isc_token_err) <<
Arg::Gds(isc_random) << Arg::Str("RETURNING_VALUES"));
}
node->outputSources = explodeOutputs(dsqlScratch, dsqlScratch->procedure);
}
if (node->outputSources)
{
for (const NestConst<ValueExprNode>* i = node->outputSources->items.begin();
i != node->outputSources->items.end();
++i)
{
AssignmentNode::dsqlValidateTarget(*i);
}
}
return node;
}
// Generate a parameter list to correspond to procedure outputs.
ValueListNode* ExecProcedureNode::explodeOutputs(DsqlCompilerScratch* dsqlScratch,
const dsql_prc* procedure)
{
DEV_BLKCHK(dsqlScratch, dsql_type_req);
DEV_BLKCHK(procedure, dsql_type_prc);
const USHORT count = procedure->prc_out_count;
ValueListNode* output = FB_NEW(getPool()) ValueListNode(getPool(), count);
NestConst<ValueExprNode>* ptr = output->items.begin();
for (const dsql_fld* field = procedure->prc_outputs; field; field = field->fld_next, ++ptr)
{
DEV_BLKCHK(field, dsql_type_fld);
ParameterNode* paramNode = FB_NEW(getPool()) ParameterNode(getPool());
*ptr = paramNode;
dsql_par* parameter = paramNode->dsqlParameter = MAKE_parameter(
dsqlScratch->getStatement()->getReceiveMsg(), true, true, 0, NULL);
paramNode->dsqlParameterIndex = parameter->par_index;
MAKE_desc_from_field(&parameter->par_desc, field);
parameter->par_name = parameter->par_alias = field->fld_name.c_str();
parameter->par_rel_name = procedure->prc_name.identifier.c_str();
parameter->par_owner_name = procedure->prc_owner.c_str();
}
return output;
}
string ExecProcedureNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlName);
NODE_PRINT(printer, inputSources);
NODE_PRINT(printer, inputTargets);
NODE_PRINT(printer, inputMessage);
NODE_PRINT(printer, outputSources);
NODE_PRINT(printer, outputTargets);
NODE_PRINT(printer, outputMessage);
return "ExecProcedureNode";
}
void ExecProcedureNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
const dsql_msg* message = NULL;
if (dsqlScratch->getStatement()->getType() == DsqlCompiledStatement::TYPE_EXEC_PROCEDURE)
{
if ((message = dsqlScratch->getStatement()->getReceiveMsg()))
{
dsqlScratch->appendUChar(blr_begin);
dsqlScratch->appendUChar(blr_send);
dsqlScratch->appendUChar(message->msg_number);
}
}
if (dsqlName.package.hasData())
{
dsqlScratch->appendUChar(blr_exec_proc2);
dsqlScratch->appendMetaString(dsqlName.package.c_str());
}
else
{
dsqlScratch->appendUChar(
(dsqlProcedure->prc_flags & PRC_subproc) ? blr_exec_subproc : blr_exec_proc);
}
dsqlScratch->appendMetaString(dsqlName.identifier.c_str());
// Input parameters.
if (inputSources)
{
dsqlScratch->appendUShort(inputSources->items.getCount());
NestConst<ValueExprNode>* ptr = inputSources->items.begin();
const NestConst<ValueExprNode>* end = inputSources->items.end();
while (ptr < end)
GEN_expr(dsqlScratch, *ptr++);
}
else
dsqlScratch->appendUShort(0);
// Output parameters.
if (outputSources)
{
dsqlScratch->appendUShort(outputSources->items.getCount());
NestConst<ValueExprNode>* ptr = outputSources->items.begin();
for (const NestConst<ValueExprNode>* end = outputSources->items.end(); ptr != end; ++ptr)
GEN_expr(dsqlScratch, *ptr);
}
else
dsqlScratch->appendUShort(0);
if (message)
dsqlScratch->appendUChar(blr_end);
}
ExecProcedureNode* ExecProcedureNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
if (!procedure->isSubRoutine())
{
// Post access to procedure.
CMP_post_procedure_access(tdbb, csb, procedure);
CMP_post_resource(&csb->csb_resources, procedure, Resource::rsc_procedure, procedure->getId());
}
doPass1(tdbb, csb, inputSources.getAddress());
doPass1(tdbb, csb, inputTargets.getAddress());
doPass1(tdbb, csb, inputMessage.getAddress());
doPass1(tdbb, csb, outputSources.getAddress());
doPass1(tdbb, csb, outputTargets.getAddress());
doPass1(tdbb, csb, outputMessage.getAddress());
return this;
}
ExecProcedureNode* ExecProcedureNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, inputSources.getAddress());
ExprNode::doPass2(tdbb, csb, inputTargets.getAddress());
doPass2(tdbb, csb, inputMessage.getAddress(), this);
ExprNode::doPass2(tdbb, csb, outputSources.getAddress());
ExprNode::doPass2(tdbb, csb, outputTargets.getAddress());
doPass2(tdbb, csb, outputMessage.getAddress(), this);
if (outputTargets)
{
for (const NestConst<ValueExprNode>* i = outputTargets->items.begin();
i != outputTargets->items.end();
++i)
{
AssignmentNode::validateTarget(csb, *i);
}
}
return this;
}
const StmtNode* ExecProcedureNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
executeProcedure(tdbb, request);
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
// Execute a stored procedure. Begin by assigning the input parameters.
// End by assigning the output parameters.
void ExecProcedureNode::executeProcedure(thread_db* tdbb, jrd_req* request) const
{
if (!procedure->isImplemented())
{
status_exception::raise(
Arg::Gds(isc_proc_pack_not_implemented) <<
Arg::Str(procedure->getName().identifier) << Arg::Str(procedure->getName().package));
}
Jrd::Attachment* attachment = tdbb->getAttachment();
ULONG inMsgLength = 0;
UCHAR* inMsg = NULL;
if (inputMessage)
{
inMsgLength = inputMessage->format->fmt_length;
inMsg = request->getImpure<UCHAR>(inputMessage->impureOffset);
}
const Format* format = NULL;
ULONG outMsgLength = 0;
UCHAR* outMsg = NULL;
Array<UCHAR> tempBuffer;
if (outputMessage)
{
format = outputMessage->format;
outMsgLength = format->fmt_length;
outMsg = request->getImpure<UCHAR>(outputMessage->impureOffset);
}
else
{
format = procedure->getOutputFormat();
outMsgLength = format->fmt_length;
outMsg = tempBuffer.getBuffer(outMsgLength + FB_DOUBLE_ALIGN - 1);
outMsg = FB_ALIGN(outMsg, FB_DOUBLE_ALIGN);
}
if (inputSources)
{
const NestConst<ValueExprNode>* const sourceEnd = inputSources->items.end();
const NestConst<ValueExprNode>* sourcePtr = inputSources->items.begin();
const NestConst<ValueExprNode>* targetPtr = inputTargets->items.begin();
for (; sourcePtr != sourceEnd; ++sourcePtr, ++targetPtr)
EXE_assignment(tdbb, *sourcePtr, *targetPtr);
}
jrd_tra* transaction = request->req_transaction;
const SLONG savePointNumber = transaction->tra_save_point ?
transaction->tra_save_point->sav_number : 0;
jrd_req* procRequest = procedure->getStatement()->findRequest(tdbb);
// trace procedure execution start
TraceProcExecute trace(tdbb, procRequest, request, inputTargets);
// Catch errors so we can unwind cleanly.
try
{
procRequest->req_timestamp = request->req_timestamp;
EXE_start(tdbb, procRequest, transaction);
if (inputMessage)
EXE_send(tdbb, procRequest, 0, inMsgLength, inMsg);
EXE_receive(tdbb, procRequest, 1, outMsgLength, outMsg);
// Clean up all savepoints started during execution of the procedure.
if (transaction != attachment->getSysTransaction())
{
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number > savePointNumber)
{
VIO_verb_cleanup(tdbb, transaction);
}
}
}
catch (const Exception& ex)
{
ex.stuffException(tdbb->tdbb_status_vector);
const bool noPriv = (tdbb->tdbb_status_vector->getErrors()[1] == isc_no_priv);
trace.finish(false,
noPriv ? Firebird::ITracePlugin::RESULT_UNAUTHORIZED : ITracePlugin::RESULT_FAILED);
EXE_unwind(tdbb, procRequest);
procRequest->req_attachment = NULL;
procRequest->req_flags &= ~(req_in_use | req_proc_fetch);
throw;
}
// trace procedure execution finish
trace.finish(false, ITracePlugin::RESULT_SUCCESS);
EXE_unwind(tdbb, procRequest);
procRequest->req_attachment = NULL;
procRequest->req_flags &= ~(req_in_use | req_proc_fetch);
if (outputSources)
{
const NestConst<ValueExprNode>* const sourceEnd = outputSources->items.end();
const NestConst<ValueExprNode>* sourcePtr = outputSources->items.begin();
const NestConst<ValueExprNode>* targetPtr = outputTargets->items.begin();
for (; sourcePtr != sourceEnd; ++sourcePtr, ++targetPtr)
EXE_assignment(tdbb, *sourcePtr, *targetPtr);
}
}
//--------------------
static RegisterNode<ExecStatementNode> regExecStatementSql(blr_exec_sql);
static RegisterNode<ExecStatementNode> regExecStatementInto(blr_exec_into);
static RegisterNode<ExecStatementNode> regExecStatementStmt(blr_exec_stmt);
DmlNode* ExecStatementNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
ExecStatementNode* node = FB_NEW(pool) ExecStatementNode(pool);
node->traScope = EDS::traCommon;
switch (blrOp)
{
case blr_exec_sql:
node->sql = PAR_parse_value(tdbb, csb);
break;
case blr_exec_into:
{
const unsigned outputs = csb->csb_blr_reader.getWord();
node->sql = PAR_parse_value(tdbb, csb);
if (csb->csb_blr_reader.getByte() == 0) // not singleton flag
node->innerStmt = PAR_parse_stmt(tdbb, csb);
node->outputs = PAR_args(tdbb, csb, outputs, outputs);
break;
}
case blr_exec_stmt:
{
unsigned inputs = 0;
unsigned outputs = 0;
while (true)
{
const UCHAR code = csb->csb_blr_reader.getByte();
switch (code)
{
case blr_exec_stmt_inputs:
inputs = csb->csb_blr_reader.getWord();
break;
case blr_exec_stmt_outputs:
outputs = csb->csb_blr_reader.getWord();
break;
case blr_exec_stmt_sql:
node->sql = PAR_parse_value(tdbb, csb);
break;
case blr_exec_stmt_proc_block:
node->innerStmt = PAR_parse_stmt(tdbb, csb);
break;
case blr_exec_stmt_data_src:
node->dataSource = PAR_parse_value(tdbb, csb);
break;
case blr_exec_stmt_user:
node->userName = PAR_parse_value(tdbb, csb);
break;
case blr_exec_stmt_pwd:
node->password = PAR_parse_value(tdbb, csb);
break;
case blr_exec_stmt_role:
node->role = PAR_parse_value(tdbb, csb);
break;
case blr_exec_stmt_tran:
PAR_syntax_error(csb, "external transaction parameters");
break;
case blr_exec_stmt_tran_clone:
node->traScope = static_cast<EDS::TraScope>(csb->csb_blr_reader.getByte());
break;
case blr_exec_stmt_privs:
node->useCallerPrivs = true;
break;
case blr_exec_stmt_in_params:
case blr_exec_stmt_in_params2:
{
node->inputs = FB_NEW(pool) ValueListNode(pool, inputs);
NestConst<ValueExprNode>* const end = node->inputs->items.end();
for (NestConst<ValueExprNode>* ptr = node->inputs->items.begin();
ptr != end;
++ptr)
{
if (code == blr_exec_stmt_in_params2)
{
MetaName name;
if (PAR_name(csb, name))
{
MemoryPool& pool = csb->csb_pool;
if (!node->inputNames)
node->inputNames = FB_NEW (pool) EDS::ParamNames(pool);
MetaName* newName = FB_NEW (pool) MetaName(pool, name);
node->inputNames->add(newName);
}
}
*ptr = PAR_parse_value(tdbb, csb);
}
break;
}
case blr_exec_stmt_out_params:
node->outputs = PAR_args(tdbb, csb, outputs, outputs);
break;
case blr_end:
break;
default:
PAR_syntax_error(csb, "unknown EXECUTE STATEMENT option");
}
if (code == blr_end)
break;
}
break;
}
default:
fb_assert(false);
}
return node;
}
StmtNode* ExecStatementNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
ExecStatementNode* node = FB_NEW(getPool()) ExecStatementNode(getPool());
node->sql = doDsqlPass(dsqlScratch, sql);
node->inputs = doDsqlPass(dsqlScratch, inputs);
node->inputNames = inputNames;
// Check params names uniqueness, if present.
if (node->inputNames)
{
const FB_SIZE_T count = node->inputNames->getCount();
StrArray names(*getDefaultMemoryPool(), count);
for (FB_SIZE_T i = 0; i != count; ++i)
{
const MetaName* name = (*node->inputNames)[i];
FB_SIZE_T pos;
if (names.find(name->c_str(), pos))
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-637) <<
Arg::Gds(isc_dsql_duplicate_spec) << *name);
}
names.insert(pos, name->c_str());
}
}
node->outputs = dsqlPassArray(dsqlScratch, outputs);
if (node->outputs)
{
for (const NestConst<ValueExprNode>* i = node->outputs->items.begin();
i != node->outputs->items.end();
++i)
{
AssignmentNode::dsqlValidateTarget(*i);
}
}
if (innerStmt)
{
++dsqlScratch->loopLevel;
node->dsqlLabelNumber = dsqlPassLabel(dsqlScratch, false, dsqlLabelName);
node->innerStmt = innerStmt->dsqlPass(dsqlScratch);
--dsqlScratch->loopLevel;
dsqlScratch->labels.pop();
}
// Process various optional arguments.
node->dataSource = doDsqlPass(dsqlScratch, dataSource);
node->userName = doDsqlPass(dsqlScratch, userName);
node->password = doDsqlPass(dsqlScratch, password);
node->role = doDsqlPass(dsqlScratch, role);
node->traScope = traScope;
node->useCallerPrivs = useCallerPrivs;
return SavepointEncloseNode::make(getPool(), dsqlScratch, node);
}
string ExecStatementNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlLabelName);
NODE_PRINT(printer, dsqlLabelNumber);
NODE_PRINT(printer, sql);
NODE_PRINT(printer, dataSource);
NODE_PRINT(printer, userName);
NODE_PRINT(printer, password);
NODE_PRINT(printer, role);
NODE_PRINT(printer, innerStmt);
NODE_PRINT(printer, inputs);
NODE_PRINT(printer, outputs);
NODE_PRINT(printer, useCallerPrivs);
NODE_PRINT(printer, traScope);
NODE_PRINT(printer, inputNames);
return "ExecStatementNode";
}
void ExecStatementNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
if (innerStmt)
{
dsqlScratch->appendUChar(blr_label);
dsqlScratch->appendUChar(dsqlLabelNumber);
}
// If no new features of EXECUTE STATEMENT are used, lets generate old BLR.
if (!dataSource && !userName && !password && !role && !useCallerPrivs && !inputs && !traScope)
{
if (outputs)
{
dsqlScratch->appendUChar(blr_exec_into);
dsqlScratch->appendUShort(outputs->items.getCount());
GEN_expr(dsqlScratch, sql);
if (innerStmt)
{
dsqlScratch->appendUChar(0); // Non-singleton.
innerStmt->genBlr(dsqlScratch);
}
else
dsqlScratch->appendUChar(1); // Singleton.
for (FB_SIZE_T i = 0; i < outputs->items.getCount(); ++i)
GEN_expr(dsqlScratch, outputs->items[i]);
}
else
{
dsqlScratch->appendUChar(blr_exec_sql);
GEN_expr(dsqlScratch, sql);
}
}
else
{
dsqlScratch->appendUChar(blr_exec_stmt);
// Counts of input and output parameters.
if (inputs)
{
dsqlScratch->appendUChar(blr_exec_stmt_inputs);
dsqlScratch->appendUShort(inputs->items.getCount());
}
if (outputs)
{
dsqlScratch->appendUChar(blr_exec_stmt_outputs);
dsqlScratch->appendUShort(outputs->items.getCount());
}
// Query expression.
dsqlScratch->appendUChar(blr_exec_stmt_sql);
GEN_expr(dsqlScratch, sql);
// Proc block body.
if (innerStmt)
{
dsqlScratch->appendUChar(blr_exec_stmt_proc_block);
innerStmt->genBlr(dsqlScratch);
}
// External data source, user, password and role.
genOptionalExpr(dsqlScratch, blr_exec_stmt_data_src, dataSource);
genOptionalExpr(dsqlScratch, blr_exec_stmt_user, userName);
genOptionalExpr(dsqlScratch, blr_exec_stmt_pwd, password);
genOptionalExpr(dsqlScratch, blr_exec_stmt_role, role);
// dsqlScratch's transaction behavior.
if (traScope)
{
// Transaction parameters equal to current transaction.
dsqlScratch->appendUChar(blr_exec_stmt_tran_clone);
dsqlScratch->appendUChar(UCHAR(traScope));
}
// Inherit caller's privileges?
if (useCallerPrivs)
dsqlScratch->appendUChar(blr_exec_stmt_privs);
// Inputs.
if (inputs)
{
if (inputNames)
dsqlScratch->appendUChar(blr_exec_stmt_in_params2);
else
dsqlScratch->appendUChar(blr_exec_stmt_in_params);
NestConst<ValueExprNode>* ptr = inputs->items.begin();
MetaName* const* name = inputNames ? inputNames->begin() : NULL;
for (const NestConst<ValueExprNode>* end = inputs->items.end(); ptr != end; ++ptr, ++name)
{
if (inputNames)
dsqlScratch->appendNullString((*name)->c_str());
GEN_expr(dsqlScratch, *ptr);
}
}
// Outputs.
if (outputs)
{
dsqlScratch->appendUChar(blr_exec_stmt_out_params);
for (FB_SIZE_T i = 0; i < outputs->items.getCount(); ++i)
GEN_expr(dsqlScratch, outputs->items[i]);
}
dsqlScratch->appendUChar(blr_end);
}
}
void ExecStatementNode::genOptionalExpr(DsqlCompilerScratch* dsqlScratch, const UCHAR code,
ValueExprNode* node)
{
if (node)
{
dsqlScratch->appendUChar(code);
GEN_expr(dsqlScratch, node);
}
}
ExecStatementNode* ExecStatementNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, sql.getAddress());
doPass1(tdbb, csb, dataSource.getAddress());
doPass1(tdbb, csb, userName.getAddress());
doPass1(tdbb, csb, password.getAddress());
doPass1(tdbb, csb, role.getAddress());
doPass1(tdbb, csb, innerStmt.getAddress());
doPass1(tdbb, csb, inputs.getAddress());
doPass1(tdbb, csb, outputs.getAddress());
return this;
}
ExecStatementNode* ExecStatementNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, sql.getAddress());
ExprNode::doPass2(tdbb, csb, dataSource.getAddress());
ExprNode::doPass2(tdbb, csb, userName.getAddress());
ExprNode::doPass2(tdbb, csb, password.getAddress());
ExprNode::doPass2(tdbb, csb, role.getAddress());
doPass2(tdbb, csb, innerStmt.getAddress(), this);
ExprNode::doPass2(tdbb, csb, inputs.getAddress());
ExprNode::doPass2(tdbb, csb, outputs.getAddress());
if (outputs)
{
for (const NestConst<ValueExprNode>* i = outputs->items.begin();
i != outputs->items.end();
++i)
{
AssignmentNode::validateTarget(csb, *i);
}
}
impureOffset = CMP_impure(csb, sizeof(EDS::Statement*));
return this;
}
const StmtNode* ExecStatementNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
EDS::Statement** stmtPtr = request->getImpure<EDS::Statement*>(impureOffset);
EDS::Statement* stmt = *stmtPtr;
if (request->req_operation == jrd_req::req_evaluate)
{
fb_assert(!*stmtPtr);
string sSql;
getString(tdbb, request, sql, sSql, true);
string sDataSrc;
getString(tdbb, request, dataSource, sDataSrc);
string sUser;
getString(tdbb, request, userName, sUser);
string sPwd;
getString(tdbb, request, password, sPwd);
string sRole;
getString(tdbb, request, role, sRole);
EDS::Connection* conn = EDS::Manager::getConnection(tdbb, sDataSrc, sUser, sPwd, sRole, traScope);
stmt = conn->createStatement(sSql);
EDS::Transaction* tran = EDS::Transaction::getTransaction(tdbb, stmt->getConnection(), traScope);
stmt->bindToRequest(request, stmtPtr);
stmt->setCallerPrivileges(useCallerPrivs);
const MetaName* const* inpNames = inputNames ? inputNames->begin() : NULL;
stmt->prepare(tdbb, tran, sSql, inputNames != NULL);
if (stmt->isSelectable())
stmt->open(tdbb, tran, inpNames, inputs, !innerStmt);
else
stmt->execute(tdbb, tran, inpNames, inputs, outputs);
request->req_operation = jrd_req::req_return;
} // jrd_req::req_evaluate
if (request->req_operation == jrd_req::req_return || request->req_operation == jrd_req::req_sync)
{
fb_assert(stmt);
if (stmt->isSelectable())
{
if (stmt->fetch(tdbb, outputs))
{
request->req_operation = jrd_req::req_evaluate;
return innerStmt;
}
request->req_operation = jrd_req::req_return;
}
}
if (request->req_operation == jrd_req::req_unwind)
{
const LabelNode* label = StmtNode::as<LabelNode>(parentStmt.getObject());
if (label && request->req_label == label->labelNumber &&
(request->req_flags & req_continue_loop))
{
request->req_flags &= ~req_continue_loop;
request->req_operation = jrd_req::req_sync;
return this;
}
}
if (stmt)
stmt->close(tdbb);
return parentStmt;
}
void ExecStatementNode::getString(thread_db* tdbb, jrd_req* request, const ValueExprNode* node,
string& str, bool useAttCS) const
{
MoveBuffer buffer;
UCHAR* p = NULL;
int len = 0;
const dsc* dsc = node ? EVL_expr(tdbb, request, node) : NULL;
if (dsc && !(request->req_flags & req_null))
{
const Jrd::Attachment* att = tdbb->getAttachment();
len = MOV_make_string2(tdbb, dsc, (useAttCS ? att->att_charset : dsc->getTextType()),
&p, buffer, false);
}
str.assign((char*) p, len);
str.trim();
}
//--------------------
static RegisterNode<IfNode> regIfNode(blr_if);
DmlNode* IfNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
IfNode* node = FB_NEW(pool) IfNode(pool);
node->condition = PAR_parse_boolean(tdbb, csb);
node->trueAction = PAR_parse_stmt(tdbb, csb);
if (csb->csb_blr_reader.peekByte() == blr_end)
csb->csb_blr_reader.getByte(); // skip blr_end
else
node->falseAction = PAR_parse_stmt(tdbb, csb);
return node;
}
IfNode* IfNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
IfNode* node = FB_NEW(getPool()) IfNode(getPool());
node->condition = doDsqlPass(dsqlScratch, condition);
node->trueAction = trueAction->dsqlPass(dsqlScratch);
if (falseAction)
node->falseAction = falseAction->dsqlPass(dsqlScratch);
return node;
}
string IfNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, condition);
NODE_PRINT(printer, trueAction);
NODE_PRINT(printer, falseAction);
return "IfNode";
}
void IfNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_if);
GEN_expr(dsqlScratch, condition);
trueAction->genBlr(dsqlScratch);
if (falseAction)
falseAction->genBlr(dsqlScratch);
else
dsqlScratch->appendUChar(blr_end);
}
IfNode* IfNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, condition.getAddress());
doPass1(tdbb, csb, trueAction.getAddress());
doPass1(tdbb, csb, falseAction.getAddress());
return this;
}
IfNode* IfNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, condition.getAddress());
doPass2(tdbb, csb, trueAction.getAddress(), this);
doPass2(tdbb, csb, falseAction.getAddress(), this);
return this;
}
const StmtNode* IfNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
if (condition->execute(tdbb, request))
{
request->req_operation = jrd_req::req_evaluate;
return trueAction;
}
if (falseAction)
{
request->req_operation = jrd_req::req_evaluate;
return falseAction;
}
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<InAutonomousTransactionNode> regInAutonomousTransactionNode(blr_auto_trans);
DmlNode* InAutonomousTransactionNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb,
const UCHAR /*blrOp*/)
{
InAutonomousTransactionNode* node = FB_NEW(pool) InAutonomousTransactionNode(pool);
if (csb->csb_blr_reader.getByte() != 0) // Reserved for future improvements. Should be 0 for now.
PAR_syntax_error(csb, "0");
node->action = PAR_parse_stmt(tdbb, csb);
return node;
}
InAutonomousTransactionNode* InAutonomousTransactionNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
const bool autoTrans = dsqlScratch->flags & DsqlCompilerScratch::FLAG_IN_AUTO_TRANS_BLOCK;
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_IN_AUTO_TRANS_BLOCK;
InAutonomousTransactionNode* node = FB_NEW(getPool()) InAutonomousTransactionNode(getPool());
node->action = action->dsqlPass(dsqlScratch);
if (!autoTrans)
dsqlScratch->flags &= ~DsqlCompilerScratch::FLAG_IN_AUTO_TRANS_BLOCK;
return node;
}
string InAutonomousTransactionNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, action);
NODE_PRINT(printer, impureOffset);
return "InAutonomousTransactionNode";
}
void InAutonomousTransactionNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_auto_trans);
dsqlScratch->appendUChar(0); // to extend syntax in the future
action->genBlr(dsqlScratch);
}
InAutonomousTransactionNode* InAutonomousTransactionNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, action.getAddress());
return this;
}
InAutonomousTransactionNode* InAutonomousTransactionNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
impureOffset = CMP_impure(csb, sizeof(Impure));
doPass2(tdbb, csb, action.getAddress(), this);
return this;
}
const StmtNode* InAutonomousTransactionNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
Database* const dbb = tdbb->getDatabase();
Jrd::Attachment* const attachment = tdbb->getAttachment();
Impure* const impure = request->getImpure<Impure>(impureOffset);
if (request->req_operation == jrd_req::req_evaluate)
{
// Force unconditional reschedule. It prevents new transactions being
// started after an attachment or a database shutdown has been initiated.
JRD_reschedule(tdbb, 0, true);
jrd_tra* const org_transaction = request->req_transaction;
fb_assert(tdbb->getTransaction() == org_transaction);
jrd_tra* const transaction = TRA_start(tdbb, org_transaction->tra_flags,
org_transaction->tra_lock_timeout,
org_transaction);
transaction->tra_flags |= org_transaction->tra_flags | TRA_db_triggers;
TRA_attach_request(transaction, request);
tdbb->setTransaction(transaction);
request->req_auto_trans.push(org_transaction);
impure->traNumber = transaction->tra_number;
VIO_start_save_point(tdbb, transaction);
impure->savNumber = transaction->tra_save_point->sav_number;
if (!(attachment->att_flags & ATT_no_db_triggers))
{
// run ON TRANSACTION START triggers
EXE_execute_db_triggers(tdbb, transaction, TRIGGER_TRANS_START);
}
return action;
}
jrd_tra* transaction = request->req_transaction;
fb_assert(transaction && transaction != attachment->getSysTransaction());
if (!impure->traNumber)
return parentStmt;
fb_assert(transaction->tra_number == impure->traNumber);
switch (request->req_operation)
{
case jrd_req::req_return:
if (!(attachment->att_flags & ATT_no_db_triggers))
{
// run ON TRANSACTION COMMIT triggers
EXE_execute_db_triggers(tdbb, transaction, TRIGGER_TRANS_COMMIT);
}
if (transaction->tra_save_point &&
!(transaction->tra_save_point->sav_flags & SAV_user) &&
!transaction->tra_save_point->sav_verb_count)
{
VIO_verb_cleanup(tdbb, transaction);
}
{ // scope
AutoSetRestore2<jrd_req*, thread_db> autoNullifyRequest(
tdbb, &thread_db::getRequest, &thread_db::setRequest, NULL);
TRA_commit(tdbb, transaction, false);
} // end scope
break;
case jrd_req::req_unwind:
if (request->req_flags & (req_leave | req_continue_loop))
{
try
{
if (!(attachment->att_flags & ATT_no_db_triggers))
{
// run ON TRANSACTION COMMIT triggers
EXE_execute_db_triggers(tdbb, transaction, TRIGGER_TRANS_COMMIT);
}
if (transaction->tra_save_point &&
!(transaction->tra_save_point->sav_flags & SAV_user) &&
!transaction->tra_save_point->sav_verb_count)
{
VIO_verb_cleanup(tdbb, transaction);
}
AutoSetRestore2<jrd_req*, thread_db> autoNullifyRequest(
tdbb, &thread_db::getRequest, &thread_db::setRequest, NULL);
TRA_commit(tdbb, transaction, false);
}
catch (...)
{
request->req_flags &= ~(req_leave | req_continue_loop);
throw;
}
}
else
{
ThreadStatusGuard temp_status(tdbb);
if (!(attachment->att_flags & ATT_no_db_triggers))
{
try
{
// run ON TRANSACTION ROLLBACK triggers
EXE_execute_db_triggers(tdbb, transaction, TRIGGER_TRANS_ROLLBACK);
}
catch (const Exception&)
{
if (dbb->dbb_flags & DBB_bugcheck)
throw;
}
}
try
{
AutoSetRestore2<jrd_req*, thread_db> autoNullifyRequest(
tdbb, &thread_db::getRequest, &thread_db::setRequest, NULL);
// undo all savepoints up to our one
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= impure->savNumber)
{
++transaction->tra_save_point->sav_verb_count;
VIO_verb_cleanup(tdbb, transaction);
}
TRA_rollback(tdbb, transaction, false, false);
}
catch (const Exception&)
{
if (dbb->dbb_flags & DBB_bugcheck)
throw;
}
}
break;
default:
fb_assert(false);
}
impure->traNumber = impure->savNumber = 0;
transaction = request->req_auto_trans.pop();
TRA_attach_request(transaction, request);
tdbb->setTransaction(transaction);
return parentStmt;
}
//--------------------
static RegisterNode<InitVariableNode> regInitVariableNode(blr_init_variable);
DmlNode* InitVariableNode::parse(thread_db* /*tdbb*/, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
InitVariableNode* node = FB_NEW(pool) InitVariableNode(pool);
node->varId = csb->csb_blr_reader.getWord();
vec<DeclareVariableNode*>* vector = csb->csb_variables;
if (!vector || node->varId >= vector->count())
PAR_error(csb, Arg::Gds(isc_badvarnum));
return node;
}
InitVariableNode* InitVariableNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string InitVariableNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, varId);
NODE_PRINT(printer, varDecl);
NODE_PRINT(printer, varInfo);
return "InitVariableNode";
}
void InitVariableNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
InitVariableNode* InitVariableNode::copy(thread_db* tdbb, NodeCopier& copier) const
{
InitVariableNode* node = FB_NEW(*tdbb->getDefaultPool()) InitVariableNode(*tdbb->getDefaultPool());
node->varId = varId + copier.csb->csb_remap_variable;
node->varDecl = varDecl;
node->varInfo = varInfo;
return node;
}
InitVariableNode* InitVariableNode::pass1(thread_db* /*tdbb*/, CompilerScratch* csb)
{
vec<DeclareVariableNode*>* vector = csb->csb_variables;
if (!vector || varId >= vector->count() || !(varDecl = (*vector)[varId]))
PAR_error(csb, Arg::Gds(isc_badvarnum));
return this;
}
InitVariableNode* InitVariableNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
varInfo = CMP_pass2_validation(tdbb, csb, Item(Item::TYPE_VARIABLE, varId));
return this;
}
const StmtNode* InitVariableNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
if (varInfo)
{
dsc* toDesc = &request->getImpure<impure_value>(varDecl->impureOffset)->vlu_desc;
toDesc->dsc_flags |= DSC_null;
MapFieldInfo::ValueType fieldInfo;
if (varInfo->fullDomain &&
request->getStatement()->mapFieldInfo.get(varInfo->field, fieldInfo) &&
fieldInfo.defaultValue)
{
dsc* value = EVL_expr(tdbb, request, fieldInfo.defaultValue);
if (value && !(request->req_flags & req_null))
{
toDesc->dsc_flags &= ~DSC_null;
MOV_move(tdbb, value, toDesc);
}
}
}
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
ExecBlockNode* ExecBlockNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
DsqlCompiledStatement* const statement = dsqlScratch->getStatement();
if (returns.hasData())
statement->setType(DsqlCompiledStatement::TYPE_SELECT_BLOCK);
else
statement->setType(DsqlCompiledStatement::TYPE_EXEC_BLOCK);
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_BLOCK;
ExecBlockNode* node = FB_NEW(getPool()) ExecBlockNode(getPool());
for (NestConst<ParameterClause>* param = parameters.begin(); param != parameters.end(); ++param)
{
PsqlChanger changer(dsqlScratch, false);
node->parameters.add(*param);
ParameterClause* newParam = node->parameters.back();
newParam->parameterExpr = doDsqlPass(dsqlScratch, newParam->parameterExpr);
if (newParam->defaultClause)
newParam->defaultClause->value = doDsqlPass(dsqlScratch, newParam->defaultClause->value);
newParam->type->resolve(dsqlScratch);
newParam->type->fld_id = param - parameters.begin();
{ // scope
ValueExprNode* temp = newParam->parameterExpr;
// Initialize this stack variable, and make it look like a node
dsc desc_node;
newParam->type->flags |= FLD_nullable;
MAKE_desc_from_field(&desc_node, newParam->type);
PASS1_set_parameter_type(dsqlScratch, temp, &desc_node, false);
} // end scope
if (param != parameters.begin())
node->parameters.end()[-2]->type->fld_next = newParam->type;
}
node->returns = returns;
for (FB_SIZE_T i = 0; i < node->returns.getCount(); ++i)
{
node->returns[i]->type->resolve(dsqlScratch);
node->returns[i]->type->fld_id = i;
if (i != 0)
node->returns[i - 1]->type->fld_next = node->returns[i]->type;
}
node->localDeclList = localDeclList;
node->body = body;
const FB_SIZE_T count = node->parameters.getCount() + node->returns.getCount() +
(node->localDeclList ? node->localDeclList->statements.getCount() : 0);
if (count != 0)
{
StrArray names(*getDefaultMemoryPool(), count);
// Hand-made PASS1_check_unique_fields_names for arrays of ParameterClause
Array<NestConst<ParameterClause> > params(parameters);
params.add(returns.begin(), returns.getCount());
for (FB_SIZE_T i = 0; i < params.getCount(); ++i)
{
ParameterClause* parameter = params[i];
FB_SIZE_T pos;
if (!names.find(parameter->name.c_str(), pos))
names.insert(pos, parameter->name.c_str());
else
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-637) <<
Arg::Gds(isc_dsql_duplicate_spec) << Arg::Str(parameter->name));
}
}
PASS1_check_unique_fields_names(names, node->localDeclList);
}
return node;
}
string ExecBlockNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, parameters);
NODE_PRINT(printer, returns);
NODE_PRINT(printer, localDeclList);
NODE_PRINT(printer, body);
return "ExecBlockNode";
}
void ExecBlockNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
thread_db* tdbb = JRD_get_thread_data();
dsqlScratch->beginDebug();
// Sub routine needs a different approach from EXECUTE BLOCK.
// EXECUTE BLOCK needs "ports", which creates DSQL messages using the client charset.
// Sub routine doesn't need ports and should generate BLR as declared in its metadata.
const bool subRoutine = dsqlScratch->flags & DsqlCompilerScratch::FLAG_SUB_ROUTINE;
unsigned returnsPos;
if (!subRoutine)
{
// Now do the input parameters.
for (FB_SIZE_T i = 0; i < parameters.getCount(); ++i)
{
ParameterClause* parameter = parameters[i];
dsqlScratch->makeVariable(parameter->type, parameter->name.c_str(),
dsql_var::TYPE_INPUT, 0, (USHORT) (2 * i), i);
}
returnsPos = dsqlScratch->variables.getCount();
// Now do the output parameters.
for (FB_SIZE_T i = 0; i < returns.getCount(); ++i)
{
ParameterClause* parameter = returns[i];
dsqlScratch->makeVariable(parameter->type, parameter->name.c_str(),
dsql_var::TYPE_OUTPUT, 1, (USHORT) (2 * i), parameters.getCount() + i);
}
}
DsqlCompiledStatement* const statement = dsqlScratch->getStatement();
dsqlScratch->appendUChar(blr_begin);
if (parameters.hasData())
{
revertParametersOrder(statement->getSendMsg()->msg_parameters);
if (!subRoutine)
GEN_port(dsqlScratch, statement->getSendMsg());
}
else
statement->setSendMsg(NULL);
for (Array<dsql_var*>::const_iterator i = dsqlScratch->outputVariables.begin();
i != dsqlScratch->outputVariables.end();
++i)
{
VariableNode* varNode = FB_NEW(*tdbb->getDefaultPool()) VariableNode(*tdbb->getDefaultPool());
varNode->dsqlVar = *i;
dsql_par* param = MAKE_parameter(statement->getReceiveMsg(), true, true,
(i - dsqlScratch->outputVariables.begin()) + 1, varNode);
param->par_node = varNode;
MAKE_desc(dsqlScratch, &param->par_desc, varNode);
param->par_desc.dsc_flags |= DSC_nullable;
}
// Set up parameter to handle EOF
dsql_par* param = MAKE_parameter(statement->getReceiveMsg(), false, false, 0, NULL);
statement->setEof(param);
param->par_desc.dsc_dtype = dtype_short;
param->par_desc.dsc_scale = 0;
param->par_desc.dsc_length = sizeof(SSHORT);
revertParametersOrder(statement->getReceiveMsg()->msg_parameters);
if (!subRoutine)
GEN_port(dsqlScratch, statement->getReceiveMsg());
if (subRoutine)
{
dsqlScratch->genParameters(parameters, returns);
returnsPos = dsqlScratch->variables.getCount() - dsqlScratch->outputVariables.getCount();
}
if (parameters.hasData())
{
dsqlScratch->appendUChar(blr_receive);
dsqlScratch->appendUChar(0);
}
dsqlScratch->appendUChar(blr_begin);
if (subRoutine)
{
// This validation is needed only for subroutines. Standard EXECUTE BLOCK moves input
// parameters to variables and are then validated.
for (unsigned i = 0; i < returnsPos; ++i)
{
const dsql_var* variable = dsqlScratch->variables[i];
const TypeClause* field = variable->field;
if (field->fullDomain || field->notNull)
{
dsqlScratch->appendUChar(blr_assignment);
dsqlScratch->appendUChar(blr_parameter2);
dsqlScratch->appendUChar(0);
dsqlScratch->appendUShort(variable->msgItem);
dsqlScratch->appendUShort(variable->msgItem + 1);
dsqlScratch->appendUChar(blr_null);
}
}
}
Array<dsql_var*>& variables = subRoutine ? dsqlScratch->outputVariables : dsqlScratch->variables;
for (Array<dsql_var*>::const_iterator i = variables.begin(); i != variables.end(); ++i)
dsqlScratch->putLocalVariable(*i, 0, NULL);
dsqlScratch->setPsql(true);
dsqlScratch->putLocalVariables(localDeclList,
USHORT((subRoutine ? 0 : parameters.getCount()) + returns.getCount()));
dsqlScratch->loopLevel = 0;
StmtNode* stmtNode = body->dsqlPass(dsqlScratch);
GEN_hidden_variables(dsqlScratch);
dsqlScratch->appendUChar(blr_stall);
// Put a label before body of procedure, so that
// any exit statement can get out
dsqlScratch->appendUChar(blr_label);
dsqlScratch->appendUChar(0);
stmtNode->genBlr(dsqlScratch);
if (returns.hasData())
statement->setType(DsqlCompiledStatement::TYPE_SELECT_BLOCK);
else
statement->setType(DsqlCompiledStatement::TYPE_EXEC_BLOCK);
dsqlScratch->appendUChar(blr_end);
dsqlScratch->genReturn(true);
dsqlScratch->appendUChar(blr_end);
dsqlScratch->endDebug();
}
// Revert parameters order for EXECUTE BLOCK statement
void ExecBlockNode::revertParametersOrder(Array<dsql_par*>& parameters)
{
int start = 0;
int end = int(parameters.getCount()) - 1;
while (start < end)
{
dsql_par* temp = parameters[start];
parameters[start] = parameters[end];
parameters[end] = temp;
++start;
--end;
}
}
//--------------------
static RegisterNode<ExceptionNode> regExceptionNode(blr_abort);
DmlNode* ExceptionNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb,
const UCHAR /*blrOp*/)
{
ExceptionNode* node = FB_NEW(pool) ExceptionNode(pool);
const UCHAR type = csb->csb_blr_reader.peekByte();
const USHORT codeType = csb->csb_blr_reader.getByte();
// Don't create ExceptionItem if blr_raise is used.
if (codeType != blr_raise)
{
ExceptionItem* const item = FB_NEW(pool) ExceptionItem(pool);
switch (codeType)
{
case blr_gds_code:
item->type = ExceptionItem::GDS_CODE;
PAR_name(csb, item->name);
item->name.lower();
if (!(item->code = PAR_symbol_to_gdscode(item->name)))
PAR_error(csb, Arg::Gds(isc_codnotdef) << item->name);
break;
case blr_exception:
case blr_exception_msg:
case blr_exception_params:
{
PAR_name(csb, item->name);
if (!MET_load_exception(tdbb, *item))
PAR_error(csb, Arg::Gds(isc_xcpnotdef) << item->name);
CompilerScratch::Dependency dependency(obj_exception);
dependency.number = item->code;
csb->csb_dependencies.push(dependency);
}
break;
default:
fb_assert(false);
break;
}
node->exception = item;
}
if (type == blr_exception_params)
{
const USHORT count = csb->csb_blr_reader.getWord();
node->parameters = PAR_args(tdbb, csb, count, count);
}
else if (type == blr_exception_msg)
node->messageExpr = PAR_parse_value(tdbb, csb);
return node;
}
StmtNode* ExceptionNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
if (parameters && parameters->items.getCount() > MsgFormat::SAFEARG_MAX_ARG)
{
status_exception::raise(
Arg::Gds(isc_dsql_max_exception_arguments) <<
Arg::Num(parameters->items.getCount()) <<
Arg::Num(MsgFormat::SAFEARG_MAX_ARG));
}
ExceptionNode* node = FB_NEW(getPool()) ExceptionNode(getPool());
if (exception)
node->exception = FB_NEW(getPool()) ExceptionItem(getPool(), *exception);
node->messageExpr = doDsqlPass(dsqlScratch, messageExpr);
node->parameters = doDsqlPass(dsqlScratch, parameters);
return SavepointEncloseNode::make(getPool(), dsqlScratch, node);
}
string ExceptionNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, messageExpr);
NODE_PRINT(printer, parameters);
NODE_PRINT(printer, exception);
return "ExceptionNode";
}
void ExceptionNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_abort);
// If exception is NULL, it means we have re-initiate semantics here,
// so blr_raise verb should be generated.
if (!exception)
{
dsqlScratch->appendUChar(blr_raise);
return;
}
// If exception value is defined, it means we have user-defined exception message
// here, so blr_exception_msg verb should be generated.
if (parameters)
dsqlScratch->appendUChar(blr_exception_params);
else if (messageExpr)
dsqlScratch->appendUChar(blr_exception_msg);
else if (exception->type == ExceptionItem::GDS_CODE)
dsqlScratch->appendUChar(blr_gds_code);
else // Otherwise go usual way, i.e. generate blr_exception.
dsqlScratch->appendUChar(blr_exception);
dsqlScratch->appendNullString(exception->name.c_str());
// If exception parameters or value is defined, generate appropriate BLR verbs.
if (parameters)
{
dsqlScratch->appendUShort(parameters->items.getCount());
NestConst<ValueExprNode>* ptr = parameters->items.begin();
const NestConst<ValueExprNode>* end = parameters->items.end();
while (ptr < end)
GEN_expr(dsqlScratch, *ptr++);
}
else if (messageExpr)
GEN_expr(dsqlScratch, messageExpr);
}
ExceptionNode* ExceptionNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, messageExpr.getAddress());
doPass1(tdbb, csb, parameters.getAddress());
if (exception)
{
CMP_post_access(tdbb, csb, exception->secName, 0,
SCL_usage, SCL_object_exception, exception->name);
}
return this;
}
ExceptionNode* ExceptionNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, messageExpr.getAddress());
ExprNode::doPass2(tdbb, csb, parameters.getAddress());
return this;
}
const StmtNode* ExceptionNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
if (exception)
{
// PsqlException is defined, so throw an exception.
setError(tdbb);
}
else if (!request->req_last_xcp.success())
{
// PsqlException is undefined, but there was a known exception before,
// so re-initiate it.
setError(tdbb);
}
else
{
// PsqlException is undefined and there weren't any exceptions before,
// so just do nothing.
request->req_operation = jrd_req::req_return;
}
}
return parentStmt;
}
// Set status vector according to specified error condition and jump to handle error accordingly.
void ExceptionNode::setError(thread_db* tdbb) const
{
SET_TDBB(tdbb);
jrd_req* request = tdbb->getRequest();
if (!exception)
{
// Retrieve the status vector and punt.
request->req_last_xcp.copyTo(tdbb->tdbb_status_vector);
request->req_last_xcp.clear();
ERR_punt();
}
MetaName exName;
MetaName relationName;
string message;
if (messageExpr)
{
// Evaluate exception message and convert it to string.
const dsc* const desc = EVL_expr(tdbb, request, messageExpr);
if (desc && !(request->req_flags & req_null))
{
MoveBuffer temp;
UCHAR* string = NULL;
const USHORT length = MOV_make_string2(tdbb, desc, CS_METADATA, &string, temp);
message.assign(string, MIN(length, XCP_MESSAGE_LENGTH));
}
}
const SLONG xcpCode = exception->code;
switch (exception->type)
{
case ExceptionItem::GDS_CODE:
if (xcpCode == isc_check_constraint)
{
MET_lookup_cnstrt_for_trigger(tdbb, exName, relationName,
request->getStatement()->triggerName);
ERR_post(Arg::Gds(xcpCode) << Arg::Str(exName) << Arg::Str(relationName));
}
else
ERR_post(Arg::Gds(xcpCode));
case ExceptionItem::XCP_CODE:
{
string tempStr;
const TEXT* s;
// CVC: If we have the exception name, use it instead of the number.
// Solves SF Bug #494981.
MET_lookup_exception(tdbb, xcpCode, exName, &tempStr);
if (message.hasData())
s = message.c_str();
else if (tempStr.hasData())
s = tempStr.c_str();
else
s = NULL;
Arg::StatusVector status;
ISC_STATUS msgCode = parameters ? isc_formatted_exception : isc_random;
if (s && exName.hasData())
{
status << Arg::Gds(isc_except) << Arg::Num(xcpCode) <<
Arg::Gds(isc_random) << Arg::Str(exName) <<
Arg::Gds(msgCode);
}
else if (s)
status << Arg::Gds(isc_except) << Arg::Num(xcpCode) <<
Arg::Gds(msgCode);
else if (exName.hasData())
{
ERR_post(Arg::Gds(isc_except) << Arg::Num(xcpCode) <<
Arg::Gds(isc_random) << Arg::Str(exName));
}
else
ERR_post(Arg::Gds(isc_except) << Arg::Num(xcpCode));
// Preallocate objects, because Arg::StatusVector store pointers.
string formattedMsg;
ObjectsArray<string> paramsStr;
if (parameters)
{
for (const NestConst<ValueExprNode>* parameter = parameters->items.begin();
parameter != parameters->items.end(); ++parameter)
{
const dsc* value = EVL_expr(tdbb, request, *parameter);
if (!value || (request->req_flags & req_null))
paramsStr.push(NULL_STRING_MARK);
else
{
// Usage of NONE here should be reviewed when exceptions are stored using
// the metadata character set.
paramsStr.push(MOV_make_string2(tdbb, value, ttype_none));
}
}
// And add the values to the args and status vector only after they are all created
// and will not move in paramsStr.
MsgFormat::SafeArg arg;
for (FB_SIZE_T i = 0; i < parameters->items.getCount(); ++i)
arg << paramsStr[i].c_str();
MsgFormat::StringRefStream stream(formattedMsg);
MsgFormat::MsgPrint(stream, s, arg, true);
status << formattedMsg;
for (FB_SIZE_T i = 0; i < parameters->items.getCount(); ++i)
status << paramsStr[i];
}
else
status << s; // add the exception text
ERR_post(status);
}
default:
fb_assert(false);
}
}
//--------------------
string ExitNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
return "ExitNode";
}
void ExitNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_leave);
dsqlScratch->appendUChar(0);
}
//--------------------
static RegisterNode<ForNode> regForNode(blr_for);
DmlNode* ForNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
ForNode* node = FB_NEW(pool) ForNode(pool);
if (csb->csb_blr_reader.peekByte() == (UCHAR) blr_stall)
node->stall = PAR_parse_stmt(tdbb, csb);
AutoSetRestore<ForNode*> autoCurrentForNode(&csb->csb_currentForNode, node);
if (csb->csb_blr_reader.peekByte() == (UCHAR) blr_rse ||
csb->csb_blr_reader.peekByte() == (UCHAR) blr_singular ||
csb->csb_blr_reader.peekByte() == (UCHAR) blr_scrollable)
{
node->rse = PAR_rse(tdbb, csb);
}
else
node->rse = PAR_rse(tdbb, csb, blrOp);
fb_assert(node->parBlrBeginCnt == 0);
node->statement = PAR_parse_stmt(tdbb, csb);
return node;
}
ForNode* ForNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
ForNode* node = FB_NEW(getPool()) ForNode(getPool());
node->dsqlCursor = dsqlCursor;
const DsqlContextStack::iterator base(*dsqlScratch->context);
if (dsqlCursor)
{
fb_assert(dsqlCursor->dsqlCursorType != DeclareCursorNode::CUR_TYPE_NONE);
PASS1_cursor_name(dsqlScratch, dsqlCursor->dsqlName, DeclareCursorNode::CUR_TYPE_ALL, false);
SelectExprNode* dt = FB_NEW(getPool()) SelectExprNode(getPool());
dt->dsqlFlags = RecordSourceNode::DFLAG_DERIVED | RecordSourceNode::DFLAG_CURSOR;
dt->querySpec = dsqlSelect->dsqlExpr;
dt->alias = dsqlCursor->dsqlName.c_str();
node->rse = PASS1_derived_table(dsqlScratch, dt, NULL, dsqlSelect->dsqlWithLock);
dsqlCursor->rse = node->rse;
dsqlCursor->cursorNumber = dsqlScratch->cursorNumber++;
dsqlScratch->cursors.push(dsqlCursor);
// ASF: We cannot write this cursor name in debug info, as dsqlScratch->cursorNumber is
// decremented below. But for now we don't need it.
}
else
node->rse = dsqlSelect->dsqlPass(dsqlScratch)->dsqlRse;
node->dsqlInto = dsqlPassArray(dsqlScratch, dsqlInto);
if (statement)
{
++dsqlScratch->scopeLevel;
// CVC: Let's add the ability to BREAK the for_select same as the while,
// but only if the command is FOR SELECT, otherwise we have singular SELECT
++dsqlScratch->loopLevel;
node->dsqlLabelNumber = dsqlPassLabel(dsqlScratch, false, dsqlLabelName);
node->statement = statement->dsqlPass(dsqlScratch);
--dsqlScratch->loopLevel;
dsqlScratch->labels.pop();
--dsqlScratch->scopeLevel;
}
dsqlScratch->context->clear(base);
if (dsqlCursor)
{
dsqlScratch->cursorNumber--;
dsqlScratch->cursors.pop();
}
return node;
}
string ForNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlSelect);
NODE_PRINT(printer, dsqlInto);
NODE_PRINT(printer, dsqlCursor);
NODE_PRINT(printer, dsqlLabelName);
NODE_PRINT(printer, dsqlLabelNumber);
NODE_PRINT(printer, dsqlForceSingular);
NODE_PRINT(printer, stall);
NODE_PRINT(printer, rse);
NODE_PRINT(printer, statement);
NODE_PRINT(printer, cursor);
NODE_PRINT(printer, parBlrBeginCnt);
return "ForNode";
}
void ForNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
// CVC: Only put a label if this is not singular; otherwise,
// what loop is the user trying to abandon?
if (statement)
{
dsqlScratch->appendUChar(blr_label);
dsqlScratch->appendUChar(dsqlLabelNumber);
}
// Generate FOR loop
dsqlScratch->appendUChar(blr_for);
if (!statement || dsqlForceSingular)
dsqlScratch->appendUChar(blr_singular);
GEN_rse(dsqlScratch, rse);
dsqlScratch->appendUChar(blr_begin);
// Build body of FOR loop
ValueListNode* list = rse->dsqlSelectList;
if (dsqlInto)
{
if (list->items.getCount() != dsqlInto->items.getCount())
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-313) <<
Arg::Gds(isc_dsql_count_mismatch));
}
NestConst<ValueExprNode>* ptr = list->items.begin();
NestConst<ValueExprNode>* ptr_to = dsqlInto->items.begin();
for (const NestConst<ValueExprNode>* const end = list->items.end(); ptr != end; ++ptr, ++ptr_to)
{
dsqlScratch->appendUChar(blr_assignment);
GEN_expr(dsqlScratch, *ptr);
GEN_expr(dsqlScratch, *ptr_to);
}
}
if (statement)
statement->genBlr(dsqlScratch);
dsqlScratch->appendUChar(blr_end);
}
StmtNode* ForNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, stall.getAddress());
doPass1(tdbb, csb, rse.getAddress());
doPass1(tdbb, csb, statement.getAddress());
return this;
}
StmtNode* ForNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
rse->pass2Rse(tdbb, csb);
doPass2(tdbb, csb, stall.getAddress(), this);
ExprNode::doPass2(tdbb, csb, rse.getAddress());
doPass2(tdbb, csb, statement.getAddress(), this);
// Finish up processing of record selection expressions.
RecordSource* const rsb = CMP_post_rse(tdbb, csb, rse.getObject());
csb->csb_fors.add(rsb);
cursor = FB_NEW(*tdbb->getDefaultPool()) Cursor(csb, rsb, rse->rse_invariants,
(rse->flags & RseNode::FLAG_SCROLLABLE));
// ASF: We cannot define the name of the cursor here, but this is not a problem,
// as implicit cursors are always positioned in a valid record, and the name is
// only used to raise isc_cursor_not_positioned.
impureOffset = CMP_impure(csb, sizeof(SLONG));
return this;
}
const StmtNode* ForNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
jrd_tra* transaction = request->req_transaction;
jrd_tra* sysTransaction = request->req_attachment->getSysTransaction();
switch (request->req_operation)
{
case jrd_req::req_evaluate:
*request->getImpure<SLONG>(impureOffset) = 0;
if (transaction != sysTransaction &&
transaction->tra_save_point && transaction->tra_save_point->sav_verb_actions)
{
VIO_start_save_point(tdbb, transaction);
const Savepoint* save_point = transaction->tra_save_point;
*request->getImpure<SLONG>(impureOffset) = save_point->sav_number;
}
cursor->open(tdbb);
request->req_records_affected.clear();
// fall into
case jrd_req::req_return:
if (stall)
return stall;
// fall into
case jrd_req::req_sync:
if (cursor->fetchNext(tdbb))
{
request->req_operation = jrd_req::req_evaluate;
return statement;
}
request->req_operation = jrd_req::req_return;
// fall into
case jrd_req::req_unwind:
{
const LabelNode* label = StmtNode::as<LabelNode>(parentStmt.getObject());
if (label && request->req_label == label->labelNumber &&
(request->req_flags & req_continue_loop))
{
request->req_flags &= ~req_continue_loop;
request->req_operation = jrd_req::req_sync;
return this;
}
// fall into
}
default:
{
const SLONG sav_number = *request->getImpure<SLONG>(impureOffset);
if (sav_number)
{
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= sav_number)
{
VIO_verb_cleanup(tdbb, transaction);
}
}
cursor->close(tdbb);
return parentStmt;
}
}
fb_assert(false); // unreachable code
return NULL;
}
//--------------------
static RegisterNode<HandlerNode> regHandlerNode(blr_handler);
DmlNode* HandlerNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
HandlerNode* node = FB_NEW(pool) HandlerNode(pool);
node->statement = PAR_parse_stmt(tdbb, csb);
return node;
}
HandlerNode* HandlerNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string HandlerNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, statement);
return "HandlerNode";
}
void HandlerNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
HandlerNode* HandlerNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, statement.getAddress());
return this;
}
HandlerNode* HandlerNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, statement.getAddress(), this);
return this;
}
const StmtNode* HandlerNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
return statement;
case jrd_req::req_unwind:
if (!request->req_label)
request->req_operation = jrd_req::req_return;
default:
return parentStmt;
}
}
//--------------------
static RegisterNode<LabelNode> regLabelNode(blr_label);
DmlNode* LabelNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
LabelNode* node = FB_NEW(pool) LabelNode(pool);
node->labelNumber = csb->csb_blr_reader.getByte();
node->statement = PAR_parse_stmt(tdbb, csb);
return node;
}
LabelNode* LabelNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string LabelNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, statement);
NODE_PRINT(printer, labelNumber);
return "LabelNode";
}
void LabelNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
LabelNode* LabelNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, statement.getAddress());
return this;
}
LabelNode* LabelNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, statement.getAddress(), this);
return this;
}
const StmtNode* LabelNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
return statement;
case jrd_req::req_unwind:
fb_assert(!(request->req_flags & req_continue_loop));
if (request->req_label == labelNumber &&
(request->req_flags & (req_leave | req_error_handler)))
{
request->req_flags &= ~req_leave;
request->req_operation = jrd_req::req_return;
}
// fall into
default:
return parentStmt;
}
}
//--------------------
string LineColumnNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, statement);
return "LineColumnNode";
}
LineColumnNode* LineColumnNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
statement = statement->dsqlPass(dsqlScratch);
return this;
}
void LineColumnNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->putDebugSrcInfo(line, column);
statement->genBlr(dsqlScratch);
}
//--------------------
static RegisterNode<LoopNode> regLoopNode(blr_loop);
DmlNode* LoopNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
LoopNode* node = FB_NEW(pool) LoopNode(pool);
node->statement = PAR_parse_stmt(tdbb, csb);
return node;
}
LoopNode* LoopNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
LoopNode* node = FB_NEW(getPool()) LoopNode(getPool());
node->dsqlExpr = doDsqlPass(dsqlScratch, dsqlExpr);
// CVC: Loop numbers should be incremented before analyzing the body
// to preserve nesting <==> increasing level number.
++dsqlScratch->loopLevel;
node->dsqlLabelNumber = dsqlPassLabel(dsqlScratch, false, dsqlLabelName);
node->statement = statement->dsqlPass(dsqlScratch);
--dsqlScratch->loopLevel;
dsqlScratch->labels.pop();
return node;
}
string LoopNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlLabelName);
NODE_PRINT(printer, dsqlLabelNumber);
NODE_PRINT(printer, dsqlExpr);
NODE_PRINT(printer, statement);
return "LoopNode";
}
void LoopNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_label);
fb_assert(dsqlLabelNumber < MAX_UCHAR);
dsqlScratch->appendUChar((UCHAR) dsqlLabelNumber);
dsqlScratch->appendUChar(blr_loop);
dsqlScratch->appendUChar(blr_begin);
dsqlScratch->appendUChar(blr_if);
GEN_expr(dsqlScratch, dsqlExpr);
statement->genBlr(dsqlScratch);
dsqlScratch->appendUChar(blr_leave);
dsqlScratch->appendUChar((UCHAR) dsqlLabelNumber);
dsqlScratch->appendUChar(blr_end);
}
LoopNode* LoopNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, statement.getAddress());
return this;
}
LoopNode* LoopNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, statement.getAddress(), this);
return this;
}
const StmtNode* LoopNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
case jrd_req::req_return:
request->req_operation = jrd_req::req_evaluate;
return statement;
case jrd_req::req_unwind:
{
const LabelNode* label = StmtNode::as<LabelNode>(parentStmt.getObject());
if (label && request->req_label == label->labelNumber &&
(request->req_flags & req_continue_loop))
{
request->req_flags &= ~req_continue_loop;
request->req_operation = jrd_req::req_evaluate;
return statement;
}
// fall into
}
default:
return parentStmt;
}
}
//--------------------
StmtNode* MergeNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
// Puts a blr_send before blr_for in DSQL statements.
class MergeSendNode : public TypedNode<DsqlOnlyStmtNode, StmtNode::TYPE_MERGE_SEND>
{
public:
MergeSendNode(MemoryPool& pool, StmtNode* aStmt)
: TypedNode<DsqlOnlyStmtNode, StmtNode::TYPE_MERGE_SEND>(pool),
stmt(aStmt)
{
}
public:
virtual string internalPrint(NodePrinter& printer) const
{
DsqlOnlyStmtNode::internalPrint(printer);
NODE_PRINT(printer, stmt);
return "MergeSendNode";
}
// Do not make dsqlPass to process 'stmt'. It's already processed.
virtual void genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsql_msg* message = dsqlScratch->getStatement()->getReceiveMsg();
if (!dsqlScratch->isPsql() && message)
{
dsqlScratch->appendUChar(blr_send);
dsqlScratch->appendUChar(message->msg_number);
}
stmt->genBlr(dsqlScratch);
}
private:
StmtNode* stmt;
};
thread_db* tdbb = JRD_get_thread_data();
MemoryPool& pool = *tdbb->getDefaultPool();
RecordSourceNode* source = usingClause; // USING
RelationSourceNode* target = relation; // INTO
// Build a join between USING and INTO tables.
RseNode* join = FB_NEW(pool) RseNode(pool);
join->dsqlExplicitJoin = true;
join->dsqlFrom = FB_NEW(pool) RecSourceListNode(pool, 2);
join->dsqlFrom->items[0] = source;
// Left join if WHEN NOT MATCHED is present.
if (whenNotMatched.hasData())
join->rse_jointype = blr_left;
join->dsqlFrom->items[1] = target;
join->dsqlWhere = condition;
RseNode* querySpec = FB_NEW(pool) RseNode(pool);
querySpec->dsqlFrom = FB_NEW(pool) RecSourceListNode(pool, 1);
querySpec->dsqlFrom->items[0] = join;
BoolExprNode* matchedConditions = NULL;
BoolExprNode* notMatchedConditions = NULL;
for (ObjectsArray<Matched>::iterator matched = whenMatched.begin();
matched != whenMatched.end();
++matched)
{
if (matched->condition)
matchedConditions = PASS1_compose(matchedConditions, matched->condition, blr_or);
else
{
matchedConditions = NULL;
break;
}
}
for (ObjectsArray<NotMatched>::iterator notMatched = whenNotMatched.begin();
notMatched != whenNotMatched.end();
++notMatched)
{
if (notMatched->condition)
notMatchedConditions = PASS1_compose(notMatchedConditions, notMatched->condition, blr_or);
else
{
notMatchedConditions = NULL;
break;
}
}
if (matchedConditions || notMatchedConditions)
{
const char* targetName = target->alias.nullStr();
if (!targetName)
targetName = target->dsqlName.c_str();
if (whenMatched.hasData()) // WHEN MATCHED
{
MissingBoolNode* missingNode = FB_NEW(pool) MissingBoolNode(
pool, FB_NEW(pool) RecordKeyNode(pool, blr_dbkey, targetName));
querySpec->dsqlWhere = FB_NEW(pool) NotBoolNode(pool, missingNode);
if (matchedConditions)
querySpec->dsqlWhere = PASS1_compose(querySpec->dsqlWhere, matchedConditions, blr_and);
}
if (whenNotMatched.hasData()) // WHEN NOT MATCHED
{
BoolExprNode* temp = FB_NEW(pool) MissingBoolNode(pool,
FB_NEW(pool) RecordKeyNode(pool, blr_dbkey, targetName));
if (notMatchedConditions)
temp = PASS1_compose(temp, notMatchedConditions, blr_and);
querySpec->dsqlWhere = PASS1_compose(querySpec->dsqlWhere, temp, blr_or);
}
}
SelectExprNode* select_expr = FB_NEW(getPool()) SelectExprNode(getPool());
select_expr->querySpec = querySpec;
// build a FOR SELECT node
ForNode* forNode = FB_NEW(pool) ForNode(pool);
forNode->dsqlSelect = FB_NEW(pool) SelectNode(pool);
forNode->dsqlSelect->dsqlExpr = select_expr;
forNode->statement = FB_NEW(pool) CompoundStmtNode(pool);
forNode = forNode->dsqlPass(dsqlScratch);
if (returning)
forNode->dsqlForceSingular = true;
// Get the already processed relations.
RseNode* processedRse = forNode->rse->dsqlStreams->items[0]->as<RseNode>();
source = processedRse->dsqlStreams->items[0];
target = processedRse->dsqlStreams->items[1]->as<RelationSourceNode>();
DsqlContextStack usingCtxs;
dsqlGetContexts(usingCtxs, source);
StmtNode* processedRet = NULL;
StmtNode* nullRet = NULL;
StmtNode* update = NULL;
IfNode* lastIf = NULL;
for (ObjectsArray<Matched>::iterator matched = whenMatched.begin();
matched != whenMatched.end();
++matched)
{
IfNode* thisIf = FB_NEW(pool) IfNode(pool);
if (matched->assignments)
{
// Get the assignments of the UPDATE dsqlScratch.
CompoundStmtNode* stmts = matched->assignments;
Array<NestConst<ValueExprNode> > orgValues, newValues;
// Separate the new and org values to process in correct contexts.
for (FB_SIZE_T i = 0; i < stmts->statements.getCount(); ++i)
{
AssignmentNode* const assign = stmts->statements[i]->as<AssignmentNode>();
fb_assert(assign);
orgValues.add(assign->asgnFrom);
newValues.add(assign->asgnTo);
}
// Build the MODIFY node.
ModifyNode* modify = FB_NEW(pool) ModifyNode(pool);
thisIf->trueAction = modify;
dsql_ctx* const oldContext = dsqlGetContext(target);
modify->dsqlContext = oldContext;
++dsqlScratch->scopeLevel; // Go to the same level of source and target contexts.
for (DsqlContextStack::iterator itr(usingCtxs); itr.hasData(); ++itr)
dsqlScratch->context->push(itr.object()); // push the USING contexts
dsqlScratch->context->push(oldContext); // process old context values
if (matched->condition)
thisIf->condition = doDsqlPass(dsqlScratch, matched->condition, false);
NestConst<ValueExprNode>* ptr;
for (ptr = orgValues.begin(); ptr != orgValues.end(); ++ptr)
*ptr = doDsqlPass(dsqlScratch, *ptr, false);
// And pop the contexts.
dsqlScratch->context->pop();
dsqlScratch->context->pop();
--dsqlScratch->scopeLevel;
// Process relation.
modify->dsqlRelation = PASS1_relation(dsqlScratch, relation);
dsql_ctx* modContext = dsqlGetContext(modify->dsqlRelation);
// Process new context values.
for (ptr = newValues.begin(); ptr != newValues.end(); ++ptr)
*ptr = doDsqlPass(dsqlScratch, *ptr, false);
dsqlScratch->context->pop();
if (returning)
{
StmtNode* updRet = ReturningProcessor::clone(dsqlScratch, returning, processedRet);
// Repush the source contexts.
++dsqlScratch->scopeLevel; // Go to the same level of source and target contexts.
for (DsqlContextStack::iterator itr(usingCtxs); itr.hasData(); ++itr)
dsqlScratch->context->push(itr.object()); // push the USING contexts
dsqlScratch->context->push(oldContext); // process old context values
modContext->ctx_scope_level = oldContext->ctx_scope_level;
processedRet = modify->statement2 = ReturningProcessor(
dsqlScratch, oldContext, modContext).process(returning, updRet);
if (!nullRet)
nullRet = dsqlNullifyReturning(dsqlScratch, modify, false);
// And pop them.
dsqlScratch->context->pop();
dsqlScratch->context->pop();
--dsqlScratch->scopeLevel;
}
// Recreate the list of assignments.
CompoundStmtNode* assignStatements = FB_NEW(pool) CompoundStmtNode(pool);
modify->statement = assignStatements;
assignStatements->statements.resize(stmts->statements.getCount());
for (FB_SIZE_T i = 0; i < assignStatements->statements.getCount(); ++i)
{
if (!PASS1_set_parameter_type(dsqlScratch, orgValues[i], newValues[i], false))
PASS1_set_parameter_type(dsqlScratch, newValues[i], orgValues[i], false);
AssignmentNode* assign = FB_NEW(pool) AssignmentNode(pool);
assign->asgnFrom = orgValues[i];
assign->asgnTo = newValues[i];
assignStatements->statements[i] = assign;
}
// We do not allow cases like UPDATE SET f1 = v1, f2 = v2, f1 = v3...
dsqlFieldAppearsOnce(newValues, "MERGE");
}
else
{
// Build the DELETE node.
EraseNode* erase = FB_NEW(pool) EraseNode(pool);
thisIf->trueAction = erase;
dsql_ctx* context = dsqlGetContext(target);
erase->dsqlContext = context;
++dsqlScratch->scopeLevel; // Go to the same level of source and target contexts.
for (DsqlContextStack::iterator itr(usingCtxs); itr.hasData(); ++itr)
dsqlScratch->context->push(itr.object()); // push the USING contexts
dsqlScratch->context->push(context); // process old context values
if (matched->condition)
thisIf->condition = doDsqlPass(dsqlScratch, matched->condition, false);
if (returning)
{
StmtNode* delRet = ReturningProcessor::clone(dsqlScratch, returning, processedRet);
processedRet = erase->statement = ReturningProcessor(
dsqlScratch, context, NULL).process(returning, delRet);
if (!nullRet)
nullRet = dsqlNullifyReturning(dsqlScratch, erase, false);
}
// And pop the contexts.
dsqlScratch->context->pop();
dsqlScratch->context->pop();
--dsqlScratch->scopeLevel;
}
if (lastIf)
lastIf->falseAction = thisIf->condition ? thisIf : thisIf->trueAction;
else
update = thisIf->condition ? thisIf : thisIf->trueAction;
lastIf = thisIf;
// If a statement executes unconditionally, no other will ever execute.
if (!thisIf->condition)
break;
}
StmtNode* insert = NULL;
lastIf = NULL;
for (ObjectsArray<NotMatched>::iterator notMatched = whenNotMatched.begin();
notMatched != whenNotMatched.end();
++notMatched)
{
IfNode* thisIf = FB_NEW(pool) IfNode(pool);
++dsqlScratch->scopeLevel; // Go to the same level of the source context.
for (DsqlContextStack::iterator itr(usingCtxs); itr.hasData(); ++itr)
dsqlScratch->context->push(itr.object()); // push the USING contexts
// The INSERT relation should be processed in a higher level than the source context.
++dsqlScratch->scopeLevel;
// Build the INSERT node.
StoreNode* store = FB_NEW(pool) StoreNode(pool);
store->dsqlRelation = relation;
store->dsqlFields = notMatched->fields;
store->dsqlValues = notMatched->values;
thisIf->trueAction = store = store->internalDsqlPass(dsqlScratch, false)->as<StoreNode>();
fb_assert(store);
if (notMatched->condition)
thisIf->condition = doDsqlPass(dsqlScratch, notMatched->condition, false);
// Restore the scope level.
--dsqlScratch->scopeLevel;
if (returning)
{
StmtNode* insRet = ReturningProcessor::clone(dsqlScratch, returning, processedRet);
dsql_ctx* const oldContext = dsqlGetContext(target);
dsqlScratch->context->push(oldContext);
dsql_ctx* context = dsqlGetContext(store->dsqlRelation);
context->ctx_scope_level = oldContext->ctx_scope_level;
processedRet = store->statement2 = ReturningProcessor(
dsqlScratch, oldContext, context).process(returning, insRet);
if (!nullRet)
nullRet = dsqlNullifyReturning(dsqlScratch, store, false);
dsqlScratch->context->pop();
}
// Pop the USING context.
dsqlScratch->context->pop();
--dsqlScratch->scopeLevel;
if (lastIf)
lastIf->falseAction = thisIf->condition ? thisIf : thisIf->trueAction;
else
insert = thisIf->condition ? thisIf : thisIf->trueAction;
lastIf = thisIf;
// If a statement executes unconditionally, no other will ever execute.
if (!thisIf->condition)
break;
}
// Build a IF (target.RDB$DB_KEY IS NULL).
IfNode* action = FB_NEW(pool) IfNode(pool);
RecordKeyNode* dbKeyNode = FB_NEW(pool) RecordKeyNode(pool, blr_dbkey);
dbKeyNode->dsqlRelation = target;
action->condition = FB_NEW(pool) MissingBoolNode(pool, dbKeyNode);
if (insert)
{
action->trueAction = insert; // then INSERT
action->falseAction = update; // else UPDATE/DELETE
}
else
{
// Negate the condition -> IF (target.RDB$DB_KEY IS NOT NULL).
action->condition = FB_NEW(pool) NotBoolNode(pool, action->condition);
action->trueAction = update; // then UPDATE/DELETE
}
if (!dsqlScratch->isPsql())
{
// Describe it as EXECUTE_PROCEDURE if RETURNING is present or as INSERT otherwise.
if (returning)
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_EXEC_PROCEDURE);
else
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_INSERT);
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_MERGE;
}
// Insert the IF inside the FOR SELECT.
forNode->statement = action;
StmtNode* mergeStmt = forNode;
// Setup the main node.
if (nullRet)
{
CompoundStmtNode* temp = FB_NEW(pool) CompoundStmtNode(pool);
temp->statements.add(nullRet);
temp->statements.add(forNode);
mergeStmt = temp;
}
StmtNode* sendNode = (FB_NEW(pool) MergeSendNode(pool, mergeStmt))->dsqlPass(dsqlScratch);
return SavepointEncloseNode::make(getPool(), dsqlScratch, sendNode);
}
string MergeNode::internalPrint(NodePrinter& printer) const
{
DsqlOnlyStmtNode::internalPrint(printer);
NODE_PRINT(printer, relation);
NODE_PRINT(printer, usingClause);
NODE_PRINT(printer, condition);
//// FIXME-PRINT: NODE_PRINT(printer, whenMatched);
//// FIXME-PRINT: NODE_PRINT(printer, whenNotMatched);
NODE_PRINT(printer, returning);
return "MergeNode";
}
void MergeNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
//--------------------
static RegisterNode<MessageNode> regMessageNode(blr_message);
// Parse a message declaration, including operator byte.
DmlNode* MessageNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
MessageNode* node = FB_NEW(pool) MessageNode(pool);
// Parse the BLR and finish the node creation.
USHORT message = csb->csb_blr_reader.getByte();
USHORT count = csb->csb_blr_reader.getWord();
node->setup(tdbb, csb, message, count);
return node;
}
void MessageNode::setup(thread_db* tdbb, CompilerScratch* csb, USHORT message, USHORT count)
{
// Register message number in the compiler scratch block, and
// allocate a node to represent the message.
CompilerScratch::csb_repeat* tail = CMP_csb_element(csb, message);
tail->csb_message = this;
messageNumber = message;
if (message > csb->csb_msg_number)
csb->csb_msg_number = message;
USHORT padField;
bool shouldPad = csb->csb_message_pad.get(messageNumber, padField);
// Get the number of parameters in the message and prepare to fill out the format block.
format = Format::newFormat(*tdbb->getDefaultPool(), count);
USHORT maxAlignment = 0;
ULONG offset = 0;
Format::fmt_desc_iterator desc, end;
USHORT index = 0;
for (desc = format->fmt_desc.begin(), end = desc + count; desc < end; ++desc, ++index)
{
ItemInfo itemInfo;
const USHORT alignment = setupDesc(tdbb, csb, index, &*desc, &itemInfo);
if (alignment)
offset = FB_ALIGN(offset, alignment);
desc->dsc_address = (UCHAR*)(IPTR) offset;
offset += desc->dsc_length;
maxAlignment = MAX(maxAlignment, alignment);
if (maxAlignment && shouldPad && index + 1 == padField)
offset = FB_ALIGN(offset, maxAlignment);
// ASF: Odd indexes are the nullable flag.
// So we only check even indexes, which is the actual parameter.
if (itemInfo.isSpecial() && index % 2 == 0)
{
csb->csb_dbg_info->argInfoToName.get(
ArgumentInfo(csb->csb_msg_number, index / 2), itemInfo.name);
csb->csb_map_item_info.put(Item(Item::TYPE_PARAMETER, csb->csb_msg_number, index),
itemInfo);
}
}
format->fmt_length = offset;
}
USHORT MessageNode::setupDesc(thread_db* tdbb, CompilerScratch* csb, USHORT /*index*/,
dsc* desc, ItemInfo* itemInfo)
{
return PAR_desc(tdbb, csb, desc, itemInfo);
}
MessageNode* MessageNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string MessageNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, messageNumber);
NODE_PRINT(printer, format);
NODE_PRINT(printer, impureFlags);
return "MessageNode";
}
void MessageNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
MessageNode* MessageNode::copy(thread_db* tdbb, NodeCopier& /*copier*/) const
{
MessageNode* node = FB_NEW(*tdbb->getDefaultPool()) MessageNode(*tdbb->getDefaultPool());
node->messageNumber = messageNumber;
node->format = format;
node->impureFlags = impureFlags;
return node;
}
MessageNode* MessageNode::pass1(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
MessageNode* MessageNode::pass2(thread_db* /*tdbb*/, CompilerScratch* csb)
{
fb_assert(format);
impureOffset = CMP_impure(csb, FB_ALIGN(format->fmt_length, 2));
impureFlags = CMP_impure(csb, sizeof(USHORT) * format->fmt_count);
return this;
}
const StmtNode* MessageNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
USHORT* flags = request->getImpure<USHORT>(impureFlags);
memset(flags, 0, sizeof(USHORT) * format->fmt_count);
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<ModifyNode> regModifyNode(blr_modify);
static RegisterNode<ModifyNode> regModifyNode2(blr_modify2);
// Parse a modify statement.
DmlNode* ModifyNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
// Parse the original and new contexts.
USHORT context = (unsigned int) csb->csb_blr_reader.getByte();
if (context >= csb->csb_rpt.getCount() || !(csb->csb_rpt[context].csb_flags & csb_used))
PAR_error(csb, Arg::Gds(isc_ctxnotdef));
const StreamType orgStream = csb->csb_rpt[context].csb_stream;
const StreamType newStream = csb->nextStream(false);
if (newStream >= MAX_STREAMS)
PAR_error(csb, Arg::Gds(isc_too_many_contexts));
context = csb->csb_blr_reader.getByte();
// Make sure the compiler scratch block is big enough to hold everything.
CompilerScratch::csb_repeat* tail = CMP_csb_element(csb, context);
tail->csb_stream = newStream;
tail->csb_flags |= csb_used;
tail = CMP_csb_element(csb, newStream);
tail->csb_relation = csb->csb_rpt[orgStream].csb_relation;
// Make the node and parse the sub-expression.
ModifyNode* node = FB_NEW(pool) ModifyNode(pool);
node->orgStream = orgStream;
node->newStream = newStream;
node->statement = PAR_parse_stmt(tdbb, csb);
if (blrOp == blr_modify2)
node->statement2 = PAR_parse_stmt(tdbb, csb);
return node;
}
StmtNode* ModifyNode::internalDsqlPass(DsqlCompilerScratch* dsqlScratch, bool updateOrInsert)
{
thread_db* tdbb = JRD_get_thread_data(); // necessary?
MemoryPool& pool = getPool();
// Separate old and new context references.
Array<NestConst<ValueExprNode> > orgValues, newValues;
CompoundStmtNode* assignments = statement->as<CompoundStmtNode>();
fb_assert(assignments);
for (FB_SIZE_T i = 0; i < assignments->statements.getCount(); ++i)
{
AssignmentNode* const assign = assignments->statements[i]->as<AssignmentNode>();
fb_assert(assign);
orgValues.add(assign->asgnFrom);
newValues.add(assign->asgnTo);
}
NestConst<RelationSourceNode> relation = dsqlRelation->as<RelationSourceNode>();
fb_assert(relation);
NestConst<ValueExprNode>* ptr;
ModifyNode* node = FB_NEW(pool) ModifyNode(pool);
if (dsqlCursorName.hasData() && dsqlScratch->isPsql())
{
node->dsqlContext = dsqlPassCursorContext(dsqlScratch, dsqlCursorName, relation);
// Process old context values.
dsqlScratch->context->push(node->dsqlContext);
++dsqlScratch->scopeLevel;
for (ptr = orgValues.begin(); ptr != orgValues.end(); ++ptr)
*ptr = doDsqlPass(dsqlScratch, *ptr, false);
--dsqlScratch->scopeLevel;
dsqlScratch->context->pop();
// Process relation.
doDsqlPass(dsqlScratch, node->dsqlRelation, relation, false);
// Process new context values.
for (ptr = newValues.begin(); ptr != newValues.end(); ++ptr)
*ptr = doDsqlPass(dsqlScratch, *ptr, false);
dsqlScratch->context->pop();
dsql_ctx* oldContext = node->dsqlContext;
dsql_ctx* modContext = dsqlGetContext(node->dsqlRelation);
dsqlScratch->context->push(oldContext); // process old context values
++dsqlScratch->scopeLevel;
node->statement2 = ReturningProcessor(dsqlScratch, oldContext, modContext).process(
dsqlReturning, statement2);
--dsqlScratch->scopeLevel;
dsqlScratch->context->pop();
// Recreate list of assignments.
CompoundStmtNode* assignStatements = FB_NEW(pool) CompoundStmtNode(pool);
node->statement = assignStatements;
assignStatements->statements.resize(assignments->statements.getCount());
for (FB_SIZE_T i = 0; i < assignStatements->statements.getCount(); ++i)
{
AssignmentNode* assign = FB_NEW(pool) AssignmentNode(pool);
assign->asgnFrom = orgValues[i];
assign->asgnTo = newValues[i];
assignStatements->statements[i] = assign;
}
// We do not allow cases like UPDATE T SET f1 = v1, f2 = v2, f1 = v3...
dsqlFieldAppearsOnce(newValues, "UPDATE");
return node;
}
dsqlScratch->getStatement()->setType(dsqlCursorName.hasData() ?
DsqlCompiledStatement::TYPE_UPDATE_CURSOR : DsqlCompiledStatement::TYPE_UPDATE);
doDsqlPass(dsqlScratch, node->dsqlRelation, relation, false);
dsql_ctx* mod_context = dsqlGetContext(node->dsqlRelation);
// Process new context values.
for (ptr = newValues.begin(); ptr != newValues.end(); ++ptr)
*ptr = doDsqlPass(dsqlScratch, *ptr, false);
dsqlScratch->context->pop();
// Generate record selection expression
RseNode* rse;
dsql_ctx* old_context;
if (dsqlCursorName.hasData())
{
rse = dsqlPassCursorReference(dsqlScratch, dsqlCursorName, relation);
old_context = rse->dsqlStreams->items[0]->dsqlContext;
}
else
{
rse = FB_NEW(pool) RseNode(pool);
rse->dsqlFlags = dsqlRseFlags;
if (dsqlReturning || statement2)
rse->dsqlFlags |= RecordSourceNode::DFLAG_SINGLETON;
rse->dsqlStreams = FB_NEW(pool) RecSourceListNode(pool, 1);
doDsqlPass(dsqlScratch, rse->dsqlStreams->items[0], relation, false);
old_context = dsqlGetContext(rse->dsqlStreams->items[0]);
if (dsqlBoolean)
rse->dsqlWhere = doDsqlPass(dsqlScratch, dsqlBoolean, false);
if (dsqlPlan)
rse->rse_plan = doDsqlPass(dsqlScratch, dsqlPlan, false);
if (dsqlOrder)
rse->dsqlOrder = PASS1_sort(dsqlScratch, dsqlOrder, NULL);
if (dsqlRows)
PASS1_limit(dsqlScratch, dsqlRows->length, dsqlRows->skip, rse);
}
if (dsqlReturning || statement2)
{
node->statement2 = ReturningProcessor(dsqlScratch, old_context, mod_context).process(
dsqlReturning, statement2);
}
node->dsqlRse = rse;
// Process old context values.
for (ptr = orgValues.begin(); ptr != orgValues.end(); ++ptr)
*ptr = doDsqlPass(dsqlScratch, *ptr, false);
dsqlScratch->context->pop();
// Recreate list of assignments.
CompoundStmtNode* assignStatements = FB_NEW(pool) CompoundStmtNode(pool);
node->statement = assignStatements;
assignStatements->statements.resize(assignments->statements.getCount());
for (FB_SIZE_T j = 0; j < assignStatements->statements.getCount(); ++j)
{
ValueExprNode* const sub1 = orgValues[j];
ValueExprNode* const sub2 = newValues[j];
if (!PASS1_set_parameter_type(dsqlScratch, sub1, sub2, false))
PASS1_set_parameter_type(dsqlScratch, sub2, sub1, false);
AssignmentNode* assign = FB_NEW(pool) AssignmentNode(pool);
assign->asgnFrom = sub1;
assign->asgnTo = sub2;
assignStatements->statements[j] = assign;
}
// We do not allow cases like UPDATE T SET f1 = v1, f2 = v2, f1 = v3...
dsqlFieldAppearsOnce(newValues, "UPDATE");
dsqlSetParametersName(assignStatements, node->dsqlRelation);
StmtNode* ret = node;
if (!updateOrInsert)
ret = dsqlNullifyReturning(dsqlScratch, node, true);
return ret;
}
StmtNode* ModifyNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
return SavepointEncloseNode::make(getPool(), dsqlScratch, internalDsqlPass(dsqlScratch, false));
}
string ModifyNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlRelation);
NODE_PRINT(printer, dsqlBoolean);
NODE_PRINT(printer, dsqlPlan);
NODE_PRINT(printer, dsqlOrder);
NODE_PRINT(printer, dsqlRows);
NODE_PRINT(printer, dsqlCursorName);
NODE_PRINT(printer, dsqlReturning);
NODE_PRINT(printer, dsqlRseFlags);
NODE_PRINT(printer, dsqlRse);
NODE_PRINT(printer, dsqlContext);
NODE_PRINT(printer, statement);
NODE_PRINT(printer, statement2);
NODE_PRINT(printer, subMod);
//// FIXME-PRINT: NODE_PRINT(printer, validations);
NODE_PRINT(printer, mapView);
NODE_PRINT(printer, orgStream);
NODE_PRINT(printer, newStream);
return "ModifyNode";
}
void ModifyNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
RseNode* rse = dsqlRse->as<RseNode>();
const dsql_msg* message = dsqlGenDmlHeader(dsqlScratch, rse);
dsqlScratch->appendUChar(statement2 ? blr_modify2 : blr_modify);
const dsql_ctx* context;
if (dsqlContext)
context = dsqlContext;
else
{
fb_assert(rse);
context = rse->dsqlStreams->items[0]->dsqlContext;
}
GEN_stuff_context(dsqlScratch, context);
context = dsqlRelation->dsqlContext;
GEN_stuff_context(dsqlScratch, context);
statement->genBlr(dsqlScratch);
if (statement2)
statement2->genBlr(dsqlScratch);
if (message)
dsqlScratch->appendUChar(blr_end);
}
ModifyNode* ModifyNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
pass1Modify(tdbb, csb, this);
doPass1(tdbb, csb, statement.getAddress());
doPass1(tdbb, csb, subMod.getAddress());
pass1Validations(tdbb, csb, validations);
doPass1(tdbb, csb, mapView.getAddress());
AutoSetRestore<bool> autoReturningExpr(&csb->csb_returning_expr, true);
doPass1(tdbb, csb, statement2.getAddress());
return this;
}
// Process a source for a modify statement. This can get a little tricky if the relation is a view.
void ModifyNode::pass1Modify(thread_db* tdbb, CompilerScratch* csb, ModifyNode* node)
{
// If updateable views with triggers are involved, there maybe a recursive call to be ignored.
if (node->subMod)
return;
jrd_rel* parent = NULL;
jrd_rel* view = NULL;
StreamType parentStream, parentNewStream;
// To support nested views, loop until we hit a table or a view with user-defined triggers
// (which means no update).
for (;;)
{
StreamType stream = node->orgStream;
StreamType newStream = node->newStream;
CompilerScratch::csb_repeat* const tail = &csb->csb_rpt[stream];
CompilerScratch::csb_repeat* const new_tail = &csb->csb_rpt[newStream];
new_tail->csb_flags |= csb_modify;
jrd_rel* const relation = tail->csb_relation;
view = relation->rel_view_rse ? relation : view;
if (!parent)
{
fb_assert(tail->csb_view == new_tail->csb_view);
parent = new_tail->csb_view;
parentStream = tail->csb_view_stream;
parentNewStream = new_tail->csb_view_stream;
}
postTriggerAccess(csb, relation, ExternalAccess::exa_update, view);
// Check out update. If this is an update thru a view, verify the view by checking for read
// access on the base table. If field-level select privileges are implemented, this needs
// to be enhanced.
SecurityClass::flags_t priv = SCL_update;
if (parent)
priv |= SCL_select;
const trig_vec* trigger = (relation->rel_pre_modify) ?
relation->rel_pre_modify : relation->rel_post_modify;
// If we have a view with triggers, let's expand it.
if (relation->rel_view_rse && trigger)
node->mapView = pass1ExpandView(tdbb, csb, stream, newStream, false);
// Get the source relation, either a table or yet another view.
RelationSourceNode* source = pass1Update(tdbb, csb, relation, trigger, stream, newStream,
priv, parent, parentStream, parentNewStream);
if (!source)
{
// No source means we're done.
if (!relation->rel_view_rse)
{
// Apply validation constraints.
makeValidation(tdbb, csb, newStream, node->validations);
}
return;
}
parent = relation;
parentStream = stream;
parentNewStream = newStream;
// Remap the source stream.
StreamType* map = tail->csb_map;
stream = source->getStream();
stream = map[stream];
// Copy the view source.
map = CMP_alloc_map(tdbb, csb, node->newStream);
NodeCopier copier(csb, map);
source = source->copy(tdbb, copier);
if (trigger)
{
// ASF: This code is responsible to make view's WITH CHECK OPTION to work as constraints.
// Set up the new target stream.
const StreamType viewStream = newStream;
newStream = source->getStream();
fb_assert(newStream <= MAX_STREAMS);
map[viewStream] = newStream;
ModifyNode* viewNode = FB_NEW(*tdbb->getDefaultPool()) ModifyNode(*tdbb->getDefaultPool());
viewNode->statement = pass1ExpandView(tdbb, csb, viewStream, newStream, true);
node->subMod = viewNode;
node = viewNode;
}
else
{
// This relation is not actually being updated as this operation
// goes deeper (we have a naturally updatable view).
csb->csb_rpt[newStream].csb_flags &= ~csb_view_update;
}
// Let's reset streams to represent the mapped source and target.
node->orgStream = stream;
node->newStream = source->getStream();
}
}
ModifyNode* ModifyNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
// AB: Mark the streams involved with UPDATE statements active.
// So that the optimizer can use indices for eventually used sub-selects.
StreamList streams;
streams.add(orgStream);
streams.add(newStream);
StreamStateHolder stateHolder(csb, streams);
stateHolder.activate();
doPass2(tdbb, csb, statement.getAddress(), this);
doPass2(tdbb, csb, statement2.getAddress(), this);
doPass2(tdbb, csb, subMod.getAddress(), this);
for (Array<ValidateInfo>::iterator i = validations.begin(); i != validations.end(); ++i)
{
ExprNode::doPass2(tdbb, csb, i->boolean.getAddress());
ExprNode::doPass2(tdbb, csb, i->value.getAddress());
}
doPass2(tdbb, csb, mapView.getAddress(), this);
csb->csb_rpt[orgStream].csb_flags |= csb_update;
const Format* format = CMP_format(tdbb, csb, orgStream);
Format::fmt_desc_const_iterator desc = format->fmt_desc.begin();
for (ULONG id = 0; id < format->fmt_count; ++id, ++desc)
{
if (desc->dsc_dtype)
SBM_SET(tdbb->getDefaultPool(), &csb->csb_rpt[orgStream].csb_fields, id);
}
impureOffset = CMP_impure(csb, sizeof(impure_state));
return this;
}
const StmtNode* ModifyNode::execute(thread_db* tdbb, jrd_req* request, ExeState* exeState) const
{
impure_state* impure = request->getImpure<impure_state>(impureOffset);
const StmtNode* retNode;
if (request->req_operation == jrd_req::req_unwind)
return parentStmt;
if (request->req_operation == jrd_req::req_return && !impure->sta_state && subMod)
{
if (!exeState->topNode)
{
exeState->topNode = this;
exeState->whichModTrig = PRE_TRIG;
}
exeState->prevNode = this;
retNode = modify(tdbb, request, exeState->whichModTrig);
if (exeState->whichModTrig == PRE_TRIG)
{
retNode = subMod;
fb_assert(retNode->parentStmt == exeState->prevNode);
///retNode->nod_parent = exeState->prevNode;
}
if (exeState->topNode == exeState->prevNode && exeState->whichModTrig == POST_TRIG)
{
exeState->topNode = NULL;
exeState->whichModTrig = ALL_TRIGS;
}
else
request->req_operation = jrd_req::req_evaluate;
}
else
{
exeState->prevNode = this;
retNode = modify(tdbb, request, ALL_TRIGS);
if (!subMod && exeState->whichModTrig == PRE_TRIG)
exeState->whichModTrig = POST_TRIG;
}
return retNode;
}
// Execute a MODIFY statement.
const StmtNode* ModifyNode::modify(thread_db* tdbb, jrd_req* request, WhichTrigger whichTrig) const
{
Jrd::Attachment* attachment = tdbb->getAttachment();
jrd_tra* transaction = request->req_transaction;
impure_state* impure = request->getImpure<impure_state>(impureOffset);
record_param* orgRpb = &request->req_rpb[orgStream];
jrd_rel* relation = orgRpb->rpb_relation;
if (orgRpb->rpb_number.isBof() || (!relation->rel_view_rse && !orgRpb->rpb_number.isValid()))
ERR_post(Arg::Gds(isc_no_cur_rec));
record_param* newRpb = &request->req_rpb[newStream];
switch (request->req_operation)
{
case jrd_req::req_evaluate:
request->req_records_affected.bumpModified(false);
break;
case jrd_req::req_return:
if (impure->sta_state == 1)
{
impure->sta_state = 0;
Record* orgRecord = orgRpb->rpb_record;
const Record* newRecord = newRpb->rpb_record;
orgRecord->copyDataFrom(newRecord, true);
request->req_operation = jrd_req::req_evaluate;
return statement;
}
if (impure->sta_state == 0)
{
// CVC: This call made here to clear the record in each NULL field and
// varchar field whose tail may contain garbage.
cleanupRpb(tdbb, newRpb);
if (transaction != attachment->getSysTransaction())
++transaction->tra_save_point->sav_verb_count;
preModifyEraseTriggers(tdbb, &relation->rel_pre_modify, whichTrig, orgRpb, newRpb,
TRIGGER_UPDATE);
if (validations.hasData())
validateExpressions(tdbb, validations);
if (relation->rel_file)
EXT_modify(orgRpb, newRpb, transaction);
else if (relation->isVirtual())
VirtualTable::modify(tdbb, orgRpb, newRpb);
else if (!relation->rel_view_rse)
{
VIO_modify(tdbb, orgRpb, newRpb, transaction);
IDX_modify(tdbb, orgRpb, newRpb, transaction);
}
newRpb->rpb_number = orgRpb->rpb_number;
newRpb->rpb_number.setValid(true);
if (relation->rel_post_modify && whichTrig != PRE_TRIG)
{
EXE_execute_triggers(tdbb, &relation->rel_post_modify, orgRpb, newRpb,
TRIGGER_UPDATE, POST_TRIG);
}
// Now call IDX_modify_check_constrints after all post modify triggers
// have fired. This is required for cascading referential integrity,
// which can be implemented as post_erase triggers.
if (!relation->rel_file && !relation->rel_view_rse && !relation->isVirtual())
IDX_modify_check_constraints(tdbb, orgRpb, newRpb, transaction);
if (transaction != attachment->getSysTransaction())
--transaction->tra_save_point->sav_verb_count;
// CVC: Increment the counter only if we called VIO/EXT_modify() and
// we were successful.
if (!(request->req_view_flags & req_first_modify_return))
{
request->req_view_flags |= req_first_modify_return;
if (relation->rel_view_rse)
request->req_top_view_modify = relation;
}
if (relation == request->req_top_view_modify)
{
if (!subMod && (whichTrig == ALL_TRIGS || whichTrig == POST_TRIG))
{
request->req_records_updated++;
request->req_records_affected.bumpModified(true);
}
}
else if (relation->rel_file || !relation->rel_view_rse)
{
request->req_records_updated++;
request->req_records_affected.bumpModified(true);
}
if (statement2)
{
impure->sta_state = 2;
request->req_operation = jrd_req::req_evaluate;
return statement2;
}
}
if (whichTrig != PRE_TRIG)
{
Record* orgRecord = orgRpb->rpb_record;
orgRpb->rpb_record = newRpb->rpb_record;
newRpb->rpb_record = orgRecord;
}
default:
return parentStmt;
}
impure->sta_state = 0;
RLCK_reserve_relation(tdbb, transaction, relation, true);
// If the stream was sorted, the various fields in the rpb are
// probably junk. Just to make sure that everything is cool,
// refetch and release the record.
if (orgRpb->rpb_runtime_flags & RPB_refetch)
{
VIO_refetch_record(tdbb, orgRpb, transaction, false);
orgRpb->rpb_runtime_flags &= ~RPB_refetch;
}
// Fall thru on evaluate to set up for modify before executing sub-statement.
// This involves finding the appropriate format, making sure a record block
// exists for the stream and is big enough, and copying fields from the
// original record to the new record.
const Format* const newFormat = MET_current(tdbb, newRpb->rpb_relation);
Record* newRecord = VIO_record(tdbb, newRpb, newFormat, tdbb->getDefaultPool());
newRpb->rpb_address = newRecord->getData();
newRpb->rpb_length = newFormat->fmt_length;
newRpb->rpb_format_number = newFormat->fmt_version;
if (!orgRpb->rpb_record)
{
const Format* const orgFormat = newFormat;
Record* const orgRecord = VIO_record(tdbb, orgRpb, orgFormat, tdbb->getDefaultPool());
orgRpb->rpb_address = orgRecord->getData();
orgRpb->rpb_length = orgFormat->fmt_length;
orgRpb->rpb_format_number = orgFormat->fmt_version;
}
// Copy the original record to the new record
VIO_copy_record(tdbb, orgRpb, newRpb);
newRpb->rpb_number = orgRpb->rpb_number;
newRpb->rpb_number.setValid(true);
if (mapView)
{
impure->sta_state = 1;
return mapView;
}
return statement;
}
//--------------------
static RegisterNode<PostEventNode> regPostEventNode1(blr_post);
static RegisterNode<PostEventNode> regPostEventNode2(blr_post_arg);
DmlNode* PostEventNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
PostEventNode* node = FB_NEW(pool) PostEventNode(pool);
node->event = PAR_parse_value(tdbb, csb);
if (blrOp == blr_post_arg)
node->argument = PAR_parse_value(tdbb, csb);
return node;
}
PostEventNode* PostEventNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
PostEventNode* node = FB_NEW(getPool()) PostEventNode(getPool());
node->event = doDsqlPass(dsqlScratch, event);
node->argument = doDsqlPass(dsqlScratch, argument);
return node;
}
string PostEventNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, event);
NODE_PRINT(printer, argument);
return "PostEventNode";
}
void PostEventNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
if (argument)
{
dsqlScratch->appendUChar(blr_post_arg);
GEN_expr(dsqlScratch, event);
GEN_expr(dsqlScratch, argument);
}
else
{
dsqlScratch->appendUChar(blr_post);
GEN_expr(dsqlScratch, event);
}
}
PostEventNode* PostEventNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, event.getAddress());
doPass1(tdbb, csb, argument.getAddress());
return this;
}
PostEventNode* PostEventNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, event.getAddress());
ExprNode::doPass2(tdbb, csb, argument.getAddress());
return this;
}
const StmtNode* PostEventNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
jrd_tra* transaction = request->req_transaction;
DeferredWork* work = DFW_post_work(transaction, dfw_post_event,
EVL_expr(tdbb, request, event), 0);
if (argument)
DFW_post_work_arg(transaction, work, EVL_expr(tdbb, request, argument), 0);
// For an autocommit transaction, events can be posted without any updates.
if (transaction->tra_flags & TRA_autocommit)
transaction->tra_flags |= TRA_perform_autocommit;
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<ReceiveNode> regReceiveNode(blr_receive);
DmlNode* ReceiveNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
ReceiveNode* node = FB_NEW(pool) ReceiveNode(pool);
USHORT n = csb->csb_blr_reader.getByte();
node->message = csb->csb_rpt[n].csb_message;
node->statement = PAR_parse_stmt(tdbb, csb);
return node;
}
ReceiveNode* ReceiveNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string ReceiveNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, statement);
NODE_PRINT(printer, message);
return "ReceiveNode";
}
void ReceiveNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
ReceiveNode* ReceiveNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, statement.getAddress());
// Do not call message pass1.
return this;
}
ReceiveNode* ReceiveNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, statement.getAddress(), this);
// Do not call message pass2.
return this;
}
// Execute a RECEIVE statement. This can be entered either with "req_evaluate" (ordinary receive
// statement) or "req_proceed" (select statement).
// In the latter case, the statement isn't every formalled evaluated.
const StmtNode* ReceiveNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
request->req_operation = jrd_req::req_receive;
request->req_message = message;
request->req_flags |= req_stall;
return this;
case jrd_req::req_proceed:
request->req_operation = jrd_req::req_evaluate;
return statement;
default:
return parentStmt;
}
}
//--------------------
static RegisterNode<StoreNode> regStoreNode(blr_store);
static RegisterNode<StoreNode> regStoreNode2(blr_store2);
// Parse a store statement.
DmlNode* StoreNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR blrOp)
{
StoreNode* node = FB_NEW(pool) StoreNode(pool);
const UCHAR* blrPos = csb->csb_blr_reader.getPos();
node->relationSource = PAR_parseRecordSource(tdbb, csb)->as<RelationSourceNode>();
if (!node->relationSource)
{
csb->csb_blr_reader.setPos(blrPos);
PAR_syntax_error(csb, "relation source");
}
node->statement = PAR_parse_stmt(tdbb, csb);
if (blrOp == blr_store2)
node->statement2 = PAR_parse_stmt(tdbb, csb);
return node;
}
StmtNode* StoreNode::internalDsqlPass(DsqlCompilerScratch* dsqlScratch, bool updateOrInsert)
{
thread_db* tdbb = JRD_get_thread_data(); // necessary?
DsqlContextStack::AutoRestore autoContext(*dsqlScratch->context);
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_INSERT);
StoreNode* node = FB_NEW(getPool()) StoreNode(getPool());
// Process SELECT expression, if present
ValueListNode* values;
if (dsqlRse)
{
SelectExprNode* selExpr = dsqlRse->as<SelectExprNode>();
fb_assert(selExpr);
if (dsqlReturning || statement2)
selExpr->dsqlFlags |= RecordSourceNode::DFLAG_SINGLETON;
RseNode* rse = PASS1_rse(dsqlScratch, selExpr, false);
node->dsqlRse = rse;
values = rse->dsqlSelectList;
}
else
values = doDsqlPass(dsqlScratch, dsqlValues, false);
// Process relation
node->dsqlRelation = PASS1_relation(dsqlScratch, dsqlRelation);
dsql_ctx* context = node->dsqlRelation->dsqlContext;
dsql_rel* relation = context->ctx_relation;
// If there isn't a field list, generate one
Array<NestConst<ValueExprNode> > fields;
if (dsqlFields.hasData())
{
for (NestConst<FieldNode>* i = dsqlFields.begin(); i != dsqlFields.end(); ++i)
{
fields.add(NULL);
doDsqlPass(dsqlScratch, fields.back(), *i, false);
}
// We do not allow cases like INSERT INTO T (f1, f2, f1)...
dsqlFieldAppearsOnce(fields, "INSERT");
// begin IBO hack
// 02-May-2004, Nickolay Samofatov. Do not constify ptr further e.g. to
// const dsql_nod* const* .... etc. It chokes GCC 3.4.0
NestConst<ValueExprNode>* ptr = fields.begin();
for (const NestConst<ValueExprNode>* const end = fields.end(); ptr != end; ++ptr)
{
const ValueExprNode* temp2 = *ptr;
const dsql_ctx* tmp_ctx = NULL;
const TEXT* tmp_name = NULL;
const FieldNode* fieldNode;
const DerivedFieldNode* derivedField;
if ((fieldNode = ExprNode::as<FieldNode>(temp2)))
{
tmp_ctx = fieldNode->dsqlContext;
if (fieldNode->dsqlField)
tmp_name = fieldNode->dsqlField->fld_name.c_str();
}
else if ((derivedField = ExprNode::as<DerivedFieldNode>(temp2)))
{
tmp_ctx = derivedField->context;
tmp_name = derivedField->name.nullStr();
}
if (tmp_ctx &&
((tmp_ctx->ctx_relation && relation->rel_name != tmp_ctx->ctx_relation->rel_name) ||
tmp_ctx->ctx_context != context->ctx_context))
{
const dsql_rel* bad_rel = tmp_ctx->ctx_relation;
PASS1_field_unknown((bad_rel ? bad_rel->rel_name.c_str() : NULL),
tmp_name, dsqlFields[ptr - fields.begin()]);
}
}
// end IBO hack
}
else
{
dsqlExplodeFields(relation, fields);
for (NestConst<ValueExprNode>* i = fields.begin(); i != fields.end(); ++i)
*i = doDsqlPass(dsqlScratch, *i, false);
}
// Match field fields and values
CompoundStmtNode* assignStatements = FB_NEW(getPool()) CompoundStmtNode(getPool());
node->statement = assignStatements;
if (values)
{
if (fields.getCount() != values->items.getCount())
{
// count of column list and value list don't match
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-804) <<
Arg::Gds(isc_dsql_var_count_err));
}
NestConst<ValueExprNode>* ptr = fields.begin();
NestConst<ValueExprNode>* ptr2 = values->items.begin();
for (const NestConst<ValueExprNode>* end = fields.end(); ptr != end; ++ptr, ++ptr2)
{
AssignmentNode* temp = FB_NEW(getPool()) AssignmentNode(getPool());
temp->asgnFrom = *ptr2;
temp->asgnTo = *ptr;
assignStatements->statements.add(temp);
PASS1_set_parameter_type(dsqlScratch, *ptr2, temp->asgnTo, false);
}
}
if (updateOrInsert)
{
// Clone the insert context, push with name "OLD" in the same scope level and
// marks it with CTX_null so all fields be resolved to NULL constant.
dsql_ctx* old_context = FB_NEW(dsqlScratch->getPool()) dsql_ctx(dsqlScratch->getPool());
*old_context = *context;
old_context->ctx_alias = old_context->ctx_internal_alias = OLD_CONTEXT_NAME;
old_context->ctx_flags |= CTX_system | CTX_null | CTX_returning;
dsqlScratch->context->push(old_context);
// clone the insert context and push with name "NEW" in a greater scope level
dsql_ctx* new_context = FB_NEW(dsqlScratch->getPool()) dsql_ctx(dsqlScratch->getPool());
*new_context = *context;
new_context->ctx_scope_level = ++dsqlScratch->scopeLevel;
new_context->ctx_alias = new_context->ctx_internal_alias = NEW_CONTEXT_NAME;
new_context->ctx_flags |= CTX_system | CTX_returning;
dsqlScratch->context->push(new_context);
}
node->statement2 = dsqlProcessReturning(dsqlScratch, dsqlReturning, statement2);
if (updateOrInsert)
{
--dsqlScratch->scopeLevel;
dsqlScratch->context->pop();
dsqlScratch->context->pop();
}
dsqlSetParametersName(assignStatements, node->dsqlRelation);
StmtNode* ret = node;
if (!updateOrInsert)
ret = dsqlNullifyReturning(dsqlScratch, node, true);
dsqlScratch->context->pop();
return ret;
}
StmtNode* StoreNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
return SavepointEncloseNode::make(getPool(), dsqlScratch, internalDsqlPass(dsqlScratch, false));
}
string StoreNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlRelation);
NODE_PRINT(printer, dsqlFields);
NODE_PRINT(printer, dsqlValues);
NODE_PRINT(printer, dsqlReturning);
NODE_PRINT(printer, dsqlRse);
NODE_PRINT(printer, statement);
NODE_PRINT(printer, statement2);
NODE_PRINT(printer, subStore);
//// FIXME-PRINT: NODE_PRINT(printer, validations);
NODE_PRINT(printer, relationSource);
return "StoreNode";
}
void StoreNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
const dsql_msg* message = dsqlGenDmlHeader(dsqlScratch, dsqlRse->as<RseNode>());
dsqlScratch->appendUChar(statement2 ? blr_store2 : blr_store);
GEN_expr(dsqlScratch, dsqlRelation);
statement->genBlr(dsqlScratch);
if (statement2)
statement2->genBlr(dsqlScratch);
if (message)
dsqlScratch->appendUChar(blr_end);
}
StoreNode* StoreNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
if (pass1Store(tdbb, csb, this))
makeDefaults(tdbb, csb);
doPass1(tdbb, csb, statement.getAddress());
doPass1(tdbb, csb, statement2.getAddress());
doPass1(tdbb, csb, subStore.getAddress());
pass1Validations(tdbb, csb, validations);
return this;
}
// Process a source for a store statement. This can get a little tricky if the relation is a view.
bool StoreNode::pass1Store(thread_db* tdbb, CompilerScratch* csb, StoreNode* node)
{
// If updateable views with triggers are involved, there may be a recursive call to be ignored.
if (node->subStore)
return false;
jrd_rel* parent = NULL;
jrd_rel* view = NULL;
StreamType parentStream;
// To support nested views, loop until we hit a table or a view with user-defined triggers
// (which means no update).
for (;;)
{
RelationSourceNode* relSource = node->relationSource;
const StreamType stream = relSource->getStream();
CompilerScratch::csb_repeat* const tail = &csb->csb_rpt[stream];
tail->csb_flags |= csb_store;
jrd_rel* const relation = tail->csb_relation;
view = relation->rel_view_rse ? relation : view;
if (!parent)
{
parent = tail->csb_view;
parentStream = tail->csb_view_stream;
}
postTriggerAccess(csb, relation, ExternalAccess::exa_insert, view);
const trig_vec* trigger = relation->rel_pre_store ?
relation->rel_pre_store : relation->rel_post_store;
// Check out insert. If this is an insert thru a view, verify the view by checking for read
// access on the base table. If field-level select privileges are implemented, this needs
// to be enhanced.
SecurityClass::flags_t priv = SCL_insert;
if (parent)
priv |= SCL_select;
// Get the source relation, either a table or yet another view.
relSource = pass1Update(tdbb, csb, relation, trigger, stream, stream,
priv, parent, parentStream, parentStream);
if (!relSource)
{
CMP_post_resource(&csb->csb_resources, relation, Resource::rsc_relation, relation->rel_id);
if (!relation->rel_view_rse)
{
// Apply validation constraints.
makeValidation(tdbb, csb, stream, node->validations);
}
return true;
}
parent = relation;
parentStream = stream;
StreamType* map = CMP_alloc_map(tdbb, csb, stream);
NodeCopier copier(csb, map);
if (trigger)
{
// ASF: This code is responsible to make view's WITH CHECK OPTION to work as constraints.
CMP_post_resource(&csb->csb_resources, relation, Resource::rsc_relation, relation->rel_id);
// Set up the new target stream.
relSource = relSource->copy(tdbb, copier);
const StreamType newStream = relSource->getStream();
StoreNode* viewNode = FB_NEW(*tdbb->getDefaultPool()) StoreNode(*tdbb->getDefaultPool());
viewNode->relationSource = relSource;
viewNode->statement = pass1ExpandView(tdbb, csb, stream, newStream, true);
node->subStore = viewNode;
// Substitute the original update node with the newly created one.
node = viewNode;
}
else
{
// This relation is not actually being updated as this operation
// goes deeper (we have a naturally updatable view).
csb->csb_rpt[stream].csb_flags &= ~csb_view_update;
node->relationSource = relSource->copy(tdbb, copier);
}
}
}
// Build a default value assignments.
void StoreNode::makeDefaults(thread_db* tdbb, CompilerScratch* csb)
{
const StreamType stream = relationSource->getStream();
jrd_rel* relation = csb->csb_rpt[stream].csb_relation;
vec<jrd_fld*>* vector = relation->rel_fields;
if (!vector)
return;
//StreamType localMap[JrdStatement::MAP_LENGTH];
AutoPtr<StreamType, ArrayDelete<StreamType> > localMap;
StreamType* map = csb->csb_rpt[stream].csb_map;
if (!map)
{
localMap = FB_NEW(*tdbb->getDefaultPool()) StreamType[STREAM_MAP_LENGTH];
map = localMap;
fb_assert(stream <= MAX_STREAMS); // CVC: MAX_UCHAR relevant, too?
map[0] = stream;
map[1] = 1;
map[2] = 2;
}
StmtNodeStack stack;
USHORT fieldId = 0;
vec<jrd_fld*>::iterator ptr1 = vector->begin();
for (const vec<jrd_fld*>::const_iterator end = vector->end(); ptr1 < end; ++ptr1, ++fieldId)
{
ValueExprNode* value;
if (!*ptr1 || !((*ptr1)->fld_generator_name.hasData() || (value = (*ptr1)->fld_default_value)))
continue;
CompoundStmtNode* compoundNode = StmtNode::as<CompoundStmtNode>(statement.getObject());
fb_assert(compoundNode);
if (compoundNode)
{
bool inList = false;
for (FB_SIZE_T i = 0; i < compoundNode->statements.getCount(); ++i)
{
const AssignmentNode* assign = StmtNode::as<AssignmentNode>(
compoundNode->statements[i].getObject());
fb_assert(assign);
if (assign)
{
const FieldNode* fieldNode = assign->asgnTo->as<FieldNode>();
fb_assert(fieldNode);
if (fieldNode && fieldNode->fieldStream == stream && fieldNode->fieldId == fieldId)
{
inList = true;
break;
}
}
}
if (inList)
continue;
AssignmentNode* assign = FB_NEW(*tdbb->getDefaultPool()) AssignmentNode(
*tdbb->getDefaultPool());
assign->asgnTo = PAR_gen_field(tdbb, stream, fieldId);
stack.push(assign);
const MetaName& generatorName = (*ptr1)->fld_generator_name;
if (generatorName.hasData())
{
// Make a gen_id(<generator name>, 1) expression.
LiteralNode* literal = FB_NEW(csb->csb_pool) LiteralNode(csb->csb_pool);
SLONG* increment = FB_NEW(csb->csb_pool) SLONG(1);
literal->litDesc.makeLong(0, increment);
GenIdNode* const genNode = FB_NEW(csb->csb_pool)
GenIdNode(csb->csb_pool, (csb->blrVersion == 4), generatorName, literal, false, true);
bool sysGen = false;
if (!MET_load_generator(tdbb, genNode->generator, &sysGen))
PAR_error(csb, Arg::Gds(isc_gennotdef) << Arg::Str(generatorName));
if (sysGen)
PAR_error(csb, Arg::Gds(isc_cant_modify_sysobj) << "generator" << generatorName);
assign->asgnFrom = genNode;
}
else //if (value)
{
// Clone the field default value.
assign->asgnFrom = RemapFieldNodeCopier(csb, map, fieldId).copy(tdbb, value);
}
}
}
if (stack.isEmpty())
return;
// We have some default - add the original statement and make a list out of the whole mess.
stack.push(statement);
statement = PAR_make_list(tdbb, stack);
}
StoreNode* StoreNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
// AB: Mark the streams involved with INSERT statements active.
// So that the optimizer can use indices for eventually used sub-selects.
StreamList streams;
streams.add(relationSource->getStream());
StreamStateHolder stateHolder(csb, streams);
stateHolder.activate();
doPass2(tdbb, csb, statement.getAddress(), this);
doPass2(tdbb, csb, statement2.getAddress(), this);
doPass2(tdbb, csb, subStore.getAddress(), this);
for (Array<ValidateInfo>::iterator i = validations.begin(); i != validations.end(); ++i)
{
ExprNode::doPass2(tdbb, csb, i->boolean.getAddress());
ExprNode::doPass2(tdbb, csb, i->value.getAddress());
}
impureOffset = CMP_impure(csb, sizeof(impure_state));
return this;
}
const StmtNode* StoreNode::execute(thread_db* tdbb, jrd_req* request, ExeState* exeState) const
{
impure_state* impure = request->getImpure<impure_state>(impureOffset);
const StmtNode* retNode;
if (request->req_operation == jrd_req::req_return && !impure->sta_state && subStore)
{
if (!exeState->topNode)
{
exeState->topNode = this;
exeState->whichStoTrig = PRE_TRIG;
}
exeState->prevNode = this;
retNode = store(tdbb, request, exeState->whichStoTrig);
if (exeState->whichStoTrig == PRE_TRIG)
{
retNode = subStore;
fb_assert(retNode->parentStmt == exeState->prevNode);
///retNode->nod_parent = exeState->prevNode;
}
if (exeState->topNode == exeState->prevNode && exeState->whichStoTrig == POST_TRIG)
{
exeState->topNode = NULL;
exeState->whichStoTrig = ALL_TRIGS;
}
else
request->req_operation = jrd_req::req_evaluate;
}
else
{
exeState->prevNode = this;
retNode = store(tdbb, request, ALL_TRIGS);
if (!subStore && exeState->whichStoTrig == PRE_TRIG)
exeState->whichStoTrig = POST_TRIG;
}
return retNode;
}
// Execute a STORE statement.
const StmtNode* StoreNode::store(thread_db* tdbb, jrd_req* request, WhichTrigger whichTrig) const
{
Jrd::Attachment* attachment = tdbb->getAttachment();
jrd_tra* transaction = request->req_transaction;
impure_state* impure = request->getImpure<impure_state>(impureOffset);
const StreamType stream = relationSource->getStream();
record_param* rpb = &request->req_rpb[stream];
jrd_rel* relation = rpb->rpb_relation;
switch (request->req_operation)
{
case jrd_req::req_evaluate:
if (!parentStmt->is<ForNode>())
request->req_records_affected.clear();
request->req_records_affected.bumpModified(false);
impure->sta_state = 0;
RLCK_reserve_relation(tdbb, transaction, relation, true);
break;
case jrd_req::req_return:
if (impure->sta_state)
return parentStmt;
if (transaction != attachment->getSysTransaction())
++transaction->tra_save_point->sav_verb_count;
if (relation->rel_pre_store && whichTrig != POST_TRIG)
{
EXE_execute_triggers(tdbb, &relation->rel_pre_store, NULL, rpb,
TRIGGER_INSERT, PRE_TRIG);
}
if (validations.hasData())
validateExpressions(tdbb, validations);
// For optimum on-disk record compression, zero all unassigned
// fields. In addition, zero the tail of assigned varying fields
// so that previous remnants don't defeat compression efficiency.
// CVC: The code that was here was moved to its own routine: cleanupRpb()
// and replaced by the call shown below.
cleanupRpb(tdbb, rpb);
if (relation->rel_file)
EXT_store(tdbb, rpb);
else if (relation->isVirtual())
VirtualTable::store(tdbb, rpb);
else if (!relation->rel_view_rse)
{
VIO_store(tdbb, rpb, transaction);
IDX_store(tdbb, rpb, transaction);
}
rpb->rpb_number.setValid(true);
if (relation->rel_post_store && whichTrig != PRE_TRIG)
{
EXE_execute_triggers(tdbb, &relation->rel_post_store, NULL, rpb,
TRIGGER_INSERT, POST_TRIG);
}
// CVC: Increment the counter only if we called VIO/EXT_store() and we were successful.
if (!(request->req_view_flags & req_first_store_return))
{
request->req_view_flags |= req_first_store_return;
if (relation->rel_view_rse)
request->req_top_view_store = relation;
}
if (relation == request->req_top_view_store)
{
if (!subStore && (whichTrig == ALL_TRIGS || whichTrig == POST_TRIG))
{
request->req_records_inserted++;
request->req_records_affected.bumpModified(true);
}
}
else if (relation->rel_file || !relation->rel_view_rse)
{
request->req_records_inserted++;
request->req_records_affected.bumpModified(true);
}
if (transaction != attachment->getSysTransaction())
--transaction->tra_save_point->sav_verb_count;
if (statement2)
{
impure->sta_state = 1;
request->req_operation = jrd_req::req_evaluate;
return statement2;
}
default:
return parentStmt;
}
// Fall thru on evaluate to set up for store before executing sub-statement.
// This involves finding the appropriate format, making sure a record block
// exists for the stream and is big enough, and initialize all null flags
// to "missing."
const Format* format = MET_current(tdbb, relation);
Record* record = VIO_record(tdbb, rpb, format, tdbb->getDefaultPool());
rpb->rpb_address = record->getData();
rpb->rpb_length = format->fmt_length;
rpb->rpb_format_number = format->fmt_version;
// dimitr: fake an invalid record number so that it could be evaluated to NULL
// even if the valid stream marker is present for OLD/NEW trigger contexts
rpb->rpb_number.setValue(BOF_NUMBER);
// CVC: This small block added by Ann Harrison to
// start with a clean empty buffer and so avoid getting
// new record buffer with misleading information. Fixes
// bug with incorrect blob sharing during insertion in
// a stored procedure.
record->nullify();
return statement;
}
//--------------------
static RegisterNode<UserSavepointNode> regUserSavepointNode(blr_user_savepoint);
DmlNode* UserSavepointNode::parse(thread_db* /*tdbb*/, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
UserSavepointNode* node = FB_NEW(pool) UserSavepointNode(pool);
node->command = (Command) csb->csb_blr_reader.getByte();
PAR_name(csb, node->name);
return node;
}
UserSavepointNode* UserSavepointNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
fb_assert(!(dsqlScratch->flags & DsqlCompilerScratch::FLAG_BLOCK));
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_SAVEPOINT);
return this;
}
string UserSavepointNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, command);
NODE_PRINT(printer, name);
return "UserSavepointNode";
}
void UserSavepointNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_user_savepoint);
dsqlScratch->appendUChar((UCHAR) command);
dsqlScratch->appendNullString(name.c_str());
}
UserSavepointNode* UserSavepointNode::pass1(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
UserSavepointNode* UserSavepointNode::pass2(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
const StmtNode* UserSavepointNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
jrd_tra* transaction = request->req_transaction;
if (request->req_operation == jrd_req::req_evaluate &&
transaction != request->req_attachment->getSysTransaction())
{
// Skip the savepoint created by EXE_start
Savepoint* savepoint = transaction->tra_save_point->sav_next;
Savepoint* previous = transaction->tra_save_point;
// Find savepoint
bool found = false;
while (true)
{
if (!savepoint || !(savepoint->sav_flags & SAV_user))
break;
if (name == savepoint->sav_name)
{
found = true;
break;
}
previous = savepoint;
savepoint = savepoint->sav_next;
}
if (!found && command != CMD_SET)
ERR_post(Arg::Gds(isc_invalid_savepoint) << Arg::Str(name));
switch (command)
{
case CMD_SET:
// Release the savepoint
if (found)
{
Savepoint* const current = transaction->tra_save_point;
transaction->tra_save_point = savepoint;
VIO_verb_cleanup(tdbb, transaction);
previous->sav_next = transaction->tra_save_point;
transaction->tra_save_point = current;
}
// Use the savepoint created by EXE_start
transaction->tra_save_point->sav_flags |= SAV_user;
transaction->tra_save_point->sav_name = name;
break;
case CMD_RELEASE_ONLY:
{
// Release the savepoint
Savepoint* const current = transaction->tra_save_point;
transaction->tra_save_point = savepoint;
VIO_verb_cleanup(tdbb, transaction);
previous->sav_next = transaction->tra_save_point;
transaction->tra_save_point = current;
break;
}
case CMD_RELEASE:
{
const SLONG sav_number = savepoint->sav_number;
// Release the savepoint and all subsequent ones
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= sav_number)
{
VIO_verb_cleanup(tdbb, transaction);
}
// Restore the savepoint initially created by EXE_start
VIO_start_save_point(tdbb, transaction);
break;
}
case CMD_ROLLBACK:
{
const SLONG sav_number = savepoint->sav_number;
// Undo the savepoint
while (transaction->tra_save_point &&
transaction->tra_save_point->sav_number >= sav_number)
{
transaction->tra_save_point->sav_verb_count++;
VIO_verb_cleanup(tdbb, transaction);
}
// Now set the savepoint again to allow to return to it later
VIO_start_save_point(tdbb, transaction);
transaction->tra_save_point->sav_flags |= SAV_user;
transaction->tra_save_point->sav_name = name;
break;
}
default:
BUGCHECK(232);
break;
}
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<SelectNode> regSelectNode(blr_select);
DmlNode* SelectNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
SelectNode* node = FB_NEW(pool) SelectNode(pool);
while (csb->csb_blr_reader.peekByte() != blr_end)
{
if (csb->csb_blr_reader.peekByte() != blr_receive)
PAR_syntax_error(csb, "blr_receive");
node->statements.add(PAR_parse_stmt(tdbb, csb));
}
csb->csb_blr_reader.getByte(); // skip blr_end
return node;
}
SelectNode* SelectNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
SelectNode* node = FB_NEW(getPool()) SelectNode(getPool());
node->dsqlForUpdate = dsqlForUpdate;
const DsqlContextStack::iterator base(*dsqlScratch->context);
node->dsqlRse = PASS1_rse(dsqlScratch, dsqlExpr, dsqlWithLock);
dsqlScratch->context->clear(base);
if (dsqlForUpdate)
{
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_SELECT_UPD);
dsqlScratch->getStatement()->addFlags(DsqlCompiledStatement::FLAG_NO_BATCH);
}
else
{
// If there is a union without ALL or order by or a select distinct buffering is OK even if
// stored procedure occurs in the select list. In these cases all of stored procedure is
// executed under savepoint for open cursor.
RseNode* rseNode = node->dsqlRse->as<RseNode>();
if (rseNode->dsqlOrder || rseNode->dsqlDistinct)
{
dsqlScratch->getStatement()->setFlags(
dsqlScratch->getStatement()->getFlags() & ~DsqlCompiledStatement::FLAG_NO_BATCH);
}
}
return node;
}
string SelectNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, dsqlExpr);
NODE_PRINT(printer, dsqlForUpdate);
NODE_PRINT(printer, dsqlWithLock);
NODE_PRINT(printer, dsqlRse);
NODE_PRINT(printer, statements);
return "SelectNode";
}
// Generate BLR for a SELECT statement.
void SelectNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
RseNode* const rse = dsqlRse->as<RseNode>();
fb_assert(rse);
DsqlCompiledStatement* const statement = dsqlScratch->getStatement();
// Set up parameter for things in the select list.
ValueListNode* list = rse->dsqlSelectList;
NestConst<ValueExprNode>* ptr = list->items.begin();
for (const NestConst<ValueExprNode>* const end = list->items.end(); ptr != end; ++ptr)
{
dsql_par* parameter = MAKE_parameter(statement->getReceiveMsg(), true, true, 0, *ptr);
parameter->par_node = *ptr;
MAKE_desc(dsqlScratch, &parameter->par_desc, *ptr);
}
// Set up parameter to handle EOF.
dsql_par* const parameterEof = MAKE_parameter(statement->getReceiveMsg(), false, false, 0, NULL);
statement->setEof(parameterEof);
parameterEof->par_desc.dsc_dtype = dtype_short;
parameterEof->par_desc.dsc_scale = 0;
parameterEof->par_desc.dsc_length = sizeof(SSHORT);
// Save DBKEYs for possible update later.
GenericMap<NonPooled<dsql_par*, dsql_ctx*> > paramContexts(*getDefaultMemoryPool());
dsql_ctx* context;
if (dsqlForUpdate && !rse->dsqlDistinct)
{
RecSourceListNode* streamList = rse->dsqlStreams;
NestConst<RecordSourceNode>* ptr2 = streamList->items.begin();
for (const NestConst<RecordSourceNode>* const end2 = streamList->items.end(); ptr2 != end2; ++ptr2)
{
RecordSourceNode* const item = *ptr2;
RelationSourceNode* relNode;
if (item && (relNode = ExprNode::as<RelationSourceNode>(item)))
{
context = relNode->dsqlContext;
const dsql_rel* const relation = context->ctx_relation;
if (relation)
{
// Set up dbkey.
dsql_par* parameter = MAKE_parameter(
statement->getReceiveMsg(), false, false, 0, NULL);
parameter->par_dbkey_relname = relation->rel_name;
paramContexts.put(parameter, context);
parameter->par_desc.dsc_dtype = dtype_text;
parameter->par_desc.dsc_ttype() = ttype_binary;
parameter->par_desc.dsc_length = relation->rel_dbkey_length;
// Set up record version.
parameter = MAKE_parameter(statement->getReceiveMsg(), false, false, 0, NULL);
parameter->par_rec_version_relname = relation->rel_name;
paramContexts.put(parameter, context);
parameter->par_desc.dsc_dtype = dtype_text;
parameter->par_desc.dsc_ttype() = ttype_binary;
parameter->par_desc.dsc_length = relation->rel_dbkey_length / 2;
}
}
}
}
// Generate definitions for the messages.
GEN_port(dsqlScratch, statement->getReceiveMsg());
dsql_msg* message = statement->getSendMsg();
if (message->msg_parameter)
GEN_port(dsqlScratch, message);
else
statement->setSendMsg(NULL);
// If there is a send message, build a RECEIVE.
if ((message = statement->getSendMsg()) != NULL)
{
dsqlScratch->appendUChar(blr_receive);
dsqlScratch->appendUChar(message->msg_number);
}
// Generate FOR loop.
message = statement->getReceiveMsg();
dsqlScratch->appendUChar(blr_for);
dsqlScratch->appendUChar(blr_stall);
GEN_rse(dsqlScratch, dsqlRse);
dsqlScratch->appendUChar(blr_send);
dsqlScratch->appendUChar(message->msg_number);
dsqlScratch->appendUChar(blr_begin);
// Build body of FOR loop.
SSHORT constant;
dsc constant_desc;
constant_desc.makeShort(0, &constant);
// Add invalid usage here.
dsqlScratch->appendUChar(blr_assignment);
constant = 1;
LiteralNode::genConstant(dsqlScratch, &constant_desc, false);
GEN_parameter(dsqlScratch, statement->getEof());
for (FB_SIZE_T i = 0; i < message->msg_parameters.getCount(); ++i)
{
dsql_par* const parameter = message->msg_parameters[i];
if (parameter->par_node)
{
dsqlScratch->appendUChar(blr_assignment);
GEN_expr(dsqlScratch, parameter->par_node);
GEN_parameter(dsqlScratch, parameter);
}
if (parameter->par_dbkey_relname.hasData() && paramContexts.get(parameter, context))
{
dsqlScratch->appendUChar(blr_assignment);
dsqlScratch->appendUChar(blr_dbkey);
GEN_stuff_context(dsqlScratch, context);
GEN_parameter(dsqlScratch, parameter);
}
if (parameter->par_rec_version_relname.hasData() && paramContexts.get(parameter, context))
{
dsqlScratch->appendUChar(blr_assignment);
dsqlScratch->appendUChar(blr_record_version);
GEN_stuff_context(dsqlScratch, context);
GEN_parameter(dsqlScratch, parameter);
}
}
dsqlScratch->appendUChar(blr_end);
dsqlScratch->appendUChar(blr_send);
dsqlScratch->appendUChar(message->msg_number);
dsqlScratch->appendUChar(blr_assignment);
constant = 0;
LiteralNode::genConstant(dsqlScratch, &constant_desc, false);
GEN_parameter(dsqlScratch, statement->getEof());
}
SelectNode* SelectNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
doPass1(tdbb, csb, i->getAddress());
return this;
}
SelectNode* SelectNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
for (NestConst<StmtNode>* i = statements.begin(); i != statements.end(); ++i)
doPass2(tdbb, csb, i->getAddress(), this);
return this;
}
// Execute a SELECT statement. This is more than a little obscure.
// We first set up the SELECT statement as the "message" and stall on receive (waiting for user send).
// EXE_send will then loop thru the sub-statements of select looking for the appropriate RECEIVE
// statement. When (or if) it finds it, it will set it up the next statement to be executed.
// The RECEIVE, then, will be entered with the operation "req_proceed".
const StmtNode* SelectNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
request->req_message = this;
request->req_operation = jrd_req::req_receive;
request->req_flags |= req_stall;
return this;
default:
return parentStmt;
}
}
//--------------------
// This is only for GPRE's cmp_set_generator().
static RegisterNode<SetGeneratorNode> regSetGeneratorNode(blr_set_generator);
DmlNode* SetGeneratorNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
MetaName name;
PAR_name(csb, name);
SetGeneratorNode* const node = FB_NEW(pool) SetGeneratorNode(pool, name);
bool sysGen = false;
if (!MET_load_generator(tdbb, node->generator, &sysGen))
PAR_error(csb, Arg::Gds(isc_gennotdef) << Arg::Str(name));
if (sysGen)
PAR_error(csb, Arg::Gds(isc_cant_modify_sysobj) << "generator" << name);
node->value = PAR_parse_value(tdbb, csb);
return node;
}
string SetGeneratorNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, generator);
NODE_PRINT(printer, value);
return "SetGeneratorNode";
}
SetGeneratorNode* SetGeneratorNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, value.getAddress());
CMP_post_access(tdbb, csb, generator.secName, 0,
SCL_usage, SCL_object_generator, generator.name);
return this;
}
SetGeneratorNode* SetGeneratorNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
ExprNode::doPass2(tdbb, csb, value.getAddress());
return this;
}
const StmtNode* SetGeneratorNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
if (request->req_operation == jrd_req::req_evaluate)
{
jrd_tra* const transaction = request->req_transaction;
DdlNode::executeDdlTrigger(tdbb, transaction, DdlNode::DTW_BEFORE,
DDL_TRIGGER_ALTER_SEQUENCE, generator.name, NULL, *request->getStatement()->sqlText);
dsc* const desc = EVL_expr(tdbb, request, value);
DPM_gen_id(tdbb, generator.id, true, MOV_get_int64(desc, 0));
DdlNode::executeDdlTrigger(tdbb, transaction, DdlNode::DTW_AFTER,
DDL_TRIGGER_ALTER_SEQUENCE, generator.name, NULL, *request->getStatement()->sqlText);
request->req_operation = jrd_req::req_return;
}
return parentStmt;
}
//--------------------
static RegisterNode<StallNode> regStallNode(blr_stall);
DmlNode* StallNode::parse(thread_db* /*tdbb*/, MemoryPool& pool, CompilerScratch* /*csb*/, const UCHAR /*blrOp*/)
{
StallNode* node = FB_NEW(pool) StallNode(pool);
return node;
}
StallNode* StallNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string StallNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
return "StallNode";
}
void StallNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
StallNode* StallNode::pass1(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
StallNode* StallNode::pass2(thread_db* /*tdbb*/, CompilerScratch* /*csb*/)
{
return this;
}
// Execute a stall statement. This is like a blr_receive, except that there is no need for a
// gds__send () from the user (i.e. EXE_send () in the engine).
// A gds__receive () will unblock the user.
const StmtNode* StallNode::execute(thread_db* /*tdbb*/, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
case jrd_req::req_return:
request->req_message = this;
request->req_operation = jrd_req::req_return;
request->req_flags |= req_stall;
return this;
case jrd_req::req_proceed:
request->req_operation = jrd_req::req_return;
return parentStmt;
default:
return parentStmt;
}
}
//--------------------
static RegisterNode<SuspendNode> regSuspendNode(blr_send);
DmlNode* SuspendNode::parse(thread_db* tdbb, MemoryPool& pool, CompilerScratch* csb, const UCHAR /*blrOp*/)
{
SuspendNode* node = FB_NEW(pool) SuspendNode(pool);
USHORT n = csb->csb_blr_reader.getByte();
node->message = csb->csb_rpt[n].csb_message;
node->statement = PAR_parse_stmt(tdbb, csb);
return node;
}
SuspendNode* SuspendNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
DsqlCompiledStatement* const statement = dsqlScratch->getStatement();
if (dsqlScratch->flags & (DsqlCompilerScratch::FLAG_TRIGGER | DsqlCompilerScratch::FLAG_FUNCTION))
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
// Token unknown
Arg::Gds(isc_token_err) <<
Arg::Gds(isc_random) << Arg::Str("SUSPEND"));
}
if (dsqlScratch->flags & DsqlCompilerScratch::FLAG_IN_AUTO_TRANS_BLOCK) // autonomous transaction
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-901) <<
Arg::Gds(isc_dsql_unsupported_in_auto_trans) << Arg::Str("SUSPEND"));
}
statement->addFlags(DsqlCompiledStatement::FLAG_SELECTABLE);
return this;
}
string SuspendNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, message);
NODE_PRINT(printer, statement);
return "SuspendNode";
}
void SuspendNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->genReturn();
}
SuspendNode* SuspendNode::pass1(thread_db* tdbb, CompilerScratch* csb)
{
doPass1(tdbb, csb, statement.getAddress());
return this;
}
SuspendNode* SuspendNode::pass2(thread_db* tdbb, CompilerScratch* csb)
{
doPass2(tdbb, csb, statement.getAddress(), this);
return this;
}
// Execute a SEND statement.
const StmtNode* SuspendNode::execute(thread_db* tdbb, jrd_req* request, ExeState* /*exeState*/) const
{
switch (request->req_operation)
{
case jrd_req::req_evaluate:
{
// ASF: If this is the send in the tail of a procedure and the procedure was called
// with a SELECT, don't run all the send statements. It may make validations fail when
// the procedure didn't return any rows. See CORE-2204.
// But we should run the last assignment, as it's the one who make the procedure stop.
if (!(request->req_flags & req_proc_fetch))
return statement;
const CompoundStmtNode* list = parentStmt->as<CompoundStmtNode>();
if (list && !list->parentStmt && list->statements[list->statements.getCount() - 1] == this)
{
list = statement->as<CompoundStmtNode>();
if (list && list->onlyAssignments && list->statements.hasData())
{
// This is the assignment that sets the EOS parameter.
const AssignmentNode* assign = static_cast<const AssignmentNode*>(
list->statements[list->statements.getCount() - 1].getObject());
EXE_assignment(tdbb, assign);
}
else
return statement;
}
else
return statement;
// fall into
}
case jrd_req::req_return:
request->req_operation = jrd_req::req_send;
request->req_message = message;
request->req_flags |= req_stall;
return this;
case jrd_req::req_proceed:
request->req_operation = jrd_req::req_return;
return parentStmt;
default:
return parentStmt;
}
}
//--------------------
ReturnNode* ReturnNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
if (!(dsqlScratch->flags & DsqlCompilerScratch::FLAG_FUNCTION))
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
// Token unknown
Arg::Gds(isc_token_err) <<
Arg::Gds(isc_random) << Arg::Str("RETURN"));
}
if (dsqlScratch->flags & DsqlCompilerScratch::FLAG_IN_AUTO_TRANS_BLOCK) // autonomous transaction
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-901) <<
Arg::Gds(isc_dsql_unsupported_in_auto_trans) << Arg::Str("RETURN"));
}
ReturnNode* node = FB_NEW(getPool()) ReturnNode(getPool());
node->value = doDsqlPass(dsqlScratch, value);
return node;
}
string ReturnNode::internalPrint(NodePrinter& printer) const
{
DsqlOnlyStmtNode::internalPrint(printer);
NODE_PRINT(printer, value);
return "ReturnNode";
}
void ReturnNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blr_begin);
dsqlScratch->appendUChar(blr_assignment);
GEN_expr(dsqlScratch, value);
dsqlScratch->appendUChar(blr_variable);
dsqlScratch->appendUShort(0);
dsqlScratch->genReturn();
dsqlScratch->appendUChar(blr_leave);
dsqlScratch->appendUChar(0);
dsqlScratch->appendUChar(blr_end);
}
//--------------------
static RegisterNode<SavePointNode> regSavePointNodeStart(blr_start_savepoint);
static RegisterNode<SavePointNode> regSavePointNodeEnd(blr_end_savepoint);
DmlNode* SavePointNode::parse(thread_db* /*tdbb*/, MemoryPool& pool, CompilerScratch* /*csb*/, const UCHAR blrOp)
{
SavePointNode* node = FB_NEW(pool) SavePointNode(pool, blrOp);
return node;
}
SavePointNode* SavePointNode::dsqlPass(DsqlCompilerScratch* /*dsqlScratch*/)
{
return this;
}
string SavePointNode::internalPrint(NodePrinter& printer) const
{
StmtNode::internalPrint(printer);
NODE_PRINT(printer, blrOp);
return "SavePointNode";
}
void SavePointNode::genBlr(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->appendUChar(blrOp);
}
const StmtNode* SavePointNode::execute(thread_db* tdbb, jrd_req* request, ExeState* exeState) const
{
jrd_tra* transaction = request->req_transaction;
jrd_tra* sysTransaction = request->req_attachment->getSysTransaction();
switch (blrOp)
{
case blr_start_savepoint:
if (request->req_operation == jrd_req::req_evaluate)
{
// Start a save point.
if (transaction != sysTransaction)
VIO_start_save_point(tdbb, transaction);
request->req_operation = jrd_req::req_return;
}
break;
case blr_end_savepoint:
if (request->req_operation == jrd_req::req_evaluate ||
request->req_operation == jrd_req::req_unwind)
{
// If any requested modify/delete/insert ops have completed, forget them.
if (transaction != sysTransaction)
{
// If an error is still pending when the savepoint is supposed to end, then the
// application didn't handle the error and the savepoint should be undone.
if (exeState->errorPending)
++transaction->tra_save_point->sav_verb_count;
VIO_verb_cleanup(tdbb, transaction);
}
if (request->req_operation == jrd_req::req_evaluate)
request->req_operation = jrd_req::req_return;
}
break;
default:
fb_assert(false);
}
return parentStmt;
}
//--------------------
SetTransactionNode* SetTransactionNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_START_TRANS);
// Generate tpb for set transaction. Use blr string of dsqlScratch.
// If a value is not specified, default is not stuffed, let the engine handle it.
fb_assert(dsqlScratch->getBlrData().getCount() == 0);
// Find out isolation level - if specified. This is required for
// specifying the correct lock level in reserving clause.
const USHORT lockLevel = isoLevel.specified && isoLevel.value == ISO_LEVEL_CONSISTENCY ?
isc_tpb_protected : isc_tpb_shared;
// Stuff some version info.
dsqlScratch->appendUChar(isc_tpb_version1);
if (readOnly.specified)
dsqlScratch->appendUChar(readOnly.value ? isc_tpb_read : isc_tpb_write);
if (wait.specified)
dsqlScratch->appendUChar(wait.value ? isc_tpb_wait : isc_tpb_nowait);
if (isoLevel.specified)
{
if (isoLevel.value == ISO_LEVEL_CONCURRENCY)
dsqlScratch->appendUChar(isc_tpb_concurrency);
else if (isoLevel.value == ISO_LEVEL_CONSISTENCY)
dsqlScratch->appendUChar(isc_tpb_consistency);
else
{
dsqlScratch->appendUChar(isc_tpb_read_committed);
if (isoLevel.value == ISO_LEVEL_READ_COMMITTED_REC_VERSION)
dsqlScratch->appendUChar(isc_tpb_rec_version);
else
dsqlScratch->appendUChar(isc_tpb_no_rec_version);
}
}
if (noAutoUndo.specified)
dsqlScratch->appendUChar(isc_tpb_no_auto_undo);
if (ignoreLimbo.specified)
dsqlScratch->appendUChar(isc_tpb_ignore_limbo);
if (restartRequests.specified)
dsqlScratch->appendUChar(isc_tpb_restart_requests);
if (lockTimeout.specified)
{
dsqlScratch->appendUChar(isc_tpb_lock_timeout);
dsqlScratch->appendUChar(2);
dsqlScratch->appendUShort(lockTimeout.value);
}
for (RestrictionOption** i = reserveList.begin(); i != reserveList.end(); ++i)
genTableLock(dsqlScratch, **i, lockLevel);
if (dsqlScratch->getBlrData().getCount() > 1) // 1 -> isc_tpb_version1
tpb.add(dsqlScratch->getBlrData().begin(), dsqlScratch->getBlrData().getCount());
return this;
}
void SetTransactionNode::execute(thread_db* tdbb, dsql_req* request, jrd_tra** transaction) const
{
JRD_start_transaction(tdbb, &request->req_transaction, request->req_dbb->dbb_attachment,
tpb.getCount(), tpb.begin());
*transaction = request->req_transaction;
}
// Generate tpb for table lock.
// If lock level is specified, it overrrides the transaction lock level.
void SetTransactionNode::genTableLock(DsqlCompilerScratch* dsqlScratch,
const RestrictionOption& tblLock, USHORT lockLevel)
{
if (tblLock.tables->isEmpty())
return;
if (tblLock.lockMode & LOCK_MODE_PROTECTED)
lockLevel = isc_tpb_protected;
else if (tblLock.lockMode & LOCK_MODE_SHARED)
lockLevel = isc_tpb_shared;
const USHORT lockMode = (tblLock.lockMode & LOCK_MODE_WRITE) ?
isc_tpb_lock_write : isc_tpb_lock_read;
for (ObjectsArray<MetaName>::iterator i = tblLock.tables->begin();
i != tblLock.tables->end();
++i)
{
dsqlScratch->appendUChar(lockMode);
dsqlScratch->appendNullString(i->c_str()); // stuff table name
dsqlScratch->appendUChar(lockLevel);
}
}
//--------------------
SetRoleNode* SetRoleNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_SET_ROLE);
return this;
}
void SetRoleNode::execute(thread_db* tdbb, dsql_req* request, jrd_tra** transaction) const
{
SET_TDBB(tdbb);
Attachment* const attachment = tdbb->getAttachment();
UserId* user = attachment->att_user;
fb_assert(user);
if (trusted)
{
if (!user->usr_trusted_role.hasData())
Arg::Gds(isc_miss_trusted_role).raise();
user->usr_sql_role_name = user->usr_trusted_role;
}
else
{
if (!SCL_role_granted(tdbb, *user, roleName.c_str()))
(Arg::Gds(isc_set_invalid_role) << roleName).raise();
user->usr_sql_role_name = roleName.c_str();
}
if (SCL_admin_role(tdbb, user->usr_sql_role_name.c_str()))
user->usr_flags |= USR_dba;
else
user->usr_flags &= ~USR_dba;
SCL_release_all(attachment->att_security_classes);
}
//--------------------
StmtNode* UpdateOrInsertNode::dsqlPass(DsqlCompilerScratch* dsqlScratch)
{
thread_db* tdbb = JRD_get_thread_data(); // necessary?
MemoryPool& pool = getPool();
if (!dsqlScratch->isPsql())
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_UPDATE_OR_INSERT;
const MetaName& relation_name = relation->as<RelationSourceNode>()->dsqlName;
MetaName base_name = relation_name;
// Build the INSERT node.
StoreNode* insert = FB_NEW(pool) StoreNode(pool);
insert->dsqlRelation = relation;
insert->dsqlFields = fields;
insert->dsqlValues = values;
insert->dsqlReturning = returning;
insert = insert->internalDsqlPass(dsqlScratch, true)->as<StoreNode>();
fb_assert(insert);
dsql_ctx* context = insert->dsqlRelation->dsqlContext;
DEV_BLKCHK(context, dsql_type_ctx);
dsql_rel* ctxRelation = context->ctx_relation;
Array<NestConst<FieldNode> > fieldsCopy = fields;
// If a field list isn't present, build one using the same rules of INSERT INTO table VALUES ...
if (fieldsCopy.isEmpty())
dsqlExplodeFields(ctxRelation, fieldsCopy);
// Maintain a pair of view's field name / base field name.
MetaNamePairMap view_fields;
if ((ctxRelation->rel_flags & REL_view) && matching.isEmpty())
{
dsql_rel* base_rel = METD_get_view_base(dsqlScratch->getTransaction(), dsqlScratch,
relation_name.c_str(), view_fields);
// Get the base table name if there is only one.
if (base_rel)
base_name = base_rel->rel_name;
else
ERRD_post(Arg::Gds(isc_upd_ins_with_complex_view));
}
Array<NestConst<FieldNode> > matchingCopy = matching;
UCHAR equality_type;
if (matching.hasData())
{
equality_type = blr_equiv;
dsqlScratch->context->push(context);
++dsqlScratch->scopeLevel;
Array<NestConst<ValueExprNode> > matchingFields;
for (NestConst<FieldNode>* i = matchingCopy.begin(); i != matchingCopy.end(); ++i)
{
PsqlChanger changer(dsqlScratch, false);
matchingFields.add((*i)->dsqlPass(dsqlScratch));
}
--dsqlScratch->scopeLevel;
dsqlScratch->context->pop();
dsqlFieldAppearsOnce(matchingFields, "UPDATE OR INSERT");
}
else
{
equality_type = blr_eql;
METD_get_primary_key(dsqlScratch->getTransaction(), base_name.c_str(), matchingCopy);
if (matchingCopy.isEmpty())
ERRD_post(Arg::Gds(isc_primary_key_required) << base_name);
}
// Build a boolean to use in the UPDATE dsqlScratch.
BoolExprNode* match = NULL;
USHORT matchCount = 0;
CompoundStmtNode* list = FB_NEW(pool) CompoundStmtNode(pool);
CompoundStmtNode* assignments = FB_NEW(pool) CompoundStmtNode(pool);
NestConst<FieldNode>* fieldPtr = fieldsCopy.begin();
NestConst<ValueExprNode>* valuePtr = values->items.begin();
Array<NestConst<StmtNode> >& insertStatements =
insert->statement->as<CompoundStmtNode>()->statements;
for (; fieldPtr != fieldsCopy.end(); ++fieldPtr, ++valuePtr)
{
AssignmentNode* assign = FB_NEW(pool) AssignmentNode(pool);
assign->asgnFrom = *valuePtr;
assign->asgnTo = *fieldPtr;
assignments->statements.add(assign);
// When relation is a view and MATCHING was not specified, fieldName
// stores the base field name that is what we should find in the primary
// key of base table.
MetaName fieldName;
if ((ctxRelation->rel_flags & REL_view) && matching.isEmpty())
view_fields.get((*fieldPtr)->dsqlName, fieldName);
else
fieldName = (*fieldPtr)->dsqlName;
if (fieldName.hasData())
{
for (NestConst<FieldNode>* matchingPtr = matchingCopy.begin();
matchingPtr != matchingCopy.end();
++matchingPtr)
{
const MetaName testField = (*matchingPtr)->dsqlName;
if (testField == fieldName)
{
++matchCount;
const FB_SIZE_T fieldPos = fieldPtr - fieldsCopy.begin();
AssignmentNode* assign2 = insertStatements[fieldPos]->as<AssignmentNode>();
NestConst<ValueExprNode>& expr = assign2->asgnFrom;
ValueExprNode* var = dsqlPassHiddenVariable(dsqlScratch, expr);
if (var)
{
AssignmentNode* varAssign = FB_NEW(pool) AssignmentNode(pool);
varAssign->asgnFrom = expr;
varAssign->asgnTo = var;
list->statements.add(varAssign);
assign2->asgnFrom = expr = var;
}
else
var = *valuePtr;
ComparativeBoolNode* eqlNode = FB_NEW(pool) ComparativeBoolNode(pool,
equality_type, *fieldPtr, var);
match = PASS1_compose(match, eqlNode, blr_and);
}
}
}
}
// check if implicit or explicit MATCHING is valid
if (matchCount != matchingCopy.getCount())
{
if (matching.hasData())
ERRD_post(Arg::Gds(isc_upd_ins_doesnt_match_matching));
else
ERRD_post(Arg::Gds(isc_upd_ins_doesnt_match_pk) << base_name);
}
// build the UPDATE node
ModifyNode* update = FB_NEW(pool) ModifyNode(pool);
update->dsqlRelation = relation;
update->statement = assignments;
update->dsqlBoolean = match;
if (returning)
{
update->dsqlRseFlags = RecordSourceNode::DFLAG_SINGLETON;
update->statement2 = ReturningProcessor::clone(
dsqlScratch, returning, insert->statement2);
}
update = update->internalDsqlPass(dsqlScratch, true)->as<ModifyNode>();
fb_assert(update);
// test if ROW_COUNT = 0
NestConst<BoolExprNode> eqlNode = FB_NEW(pool) ComparativeBoolNode(pool, blr_eql,
FB_NEW(pool) InternalInfoNode(pool, MAKE_const_slong(INFO_TYPE_ROWS_AFFECTED)),
MAKE_const_slong(0));
const ULONG save_flags = dsqlScratch->flags;
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_BLOCK; // to compile ROW_COUNT
eqlNode = doDsqlPass(dsqlScratch, eqlNode);
dsqlScratch->flags = save_flags;
// If (ROW_COUNT = 0) then INSERT.
IfNode* ifNode = FB_NEW(pool) IfNode(pool);
ifNode->condition = eqlNode;
ifNode->trueAction = insert;
// Build the temporary vars / UPDATE / IF nodes.
list->statements.add(update);
list->statements.add(ifNode);
// If RETURNING is present, type is already DsqlCompiledStatement::TYPE_EXEC_PROCEDURE.
if (!returning)
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_INSERT);
return SavepointEncloseNode::make(getPool(), dsqlScratch, list);
}
string UpdateOrInsertNode::internalPrint(NodePrinter& printer) const
{
DsqlOnlyStmtNode::internalPrint(printer);
NODE_PRINT(printer, relation);
NODE_PRINT(printer, fields);
NODE_PRINT(printer, values);
NODE_PRINT(printer, matching);
NODE_PRINT(printer, returning);
return "UpdateOrInsertNode";
}
void UpdateOrInsertNode::genBlr(DsqlCompilerScratch* /*dsqlScratch*/)
{
}
//--------------------
// Generate a field list that correspond to table fields.
template <typename T>
static void dsqlExplodeFields(dsql_rel* relation, Array<NestConst<T> >& fields)
{
thread_db* tdbb = JRD_get_thread_data();
MemoryPool& pool = *tdbb->getDefaultPool();
for (dsql_fld* field = relation->rel_fields; field; field = field->fld_next)
{
// CVC: Ann Harrison requested to skip COMPUTED fields in INSERT w/o field list.
if (field->flags & FLD_computed)
continue;
FieldNode* fieldNode = FB_NEW(pool) FieldNode(pool);
fieldNode->dsqlName = field->fld_name.c_str();
fields.add(fieldNode);
}
}
// Find dbkey for named relation in statement's saved dbkeys.
static dsql_par* dsqlFindDbKey(const dsql_req* request, const RelationSourceNode* relation_name)
{
DEV_BLKCHK(request, dsql_type_req);
DEV_BLKCHK(relation_name, dsql_type_nod);
const dsql_msg* message = request->getStatement()->getReceiveMsg();
dsql_par* candidate = NULL;
const MetaName& relName = relation_name->dsqlName;
for (FB_SIZE_T i = 0; i < message->msg_parameters.getCount(); ++i)
{
dsql_par* parameter = message->msg_parameters[i];
if (parameter->par_dbkey_relname.hasData() && parameter->par_dbkey_relname == relName)
{
if (candidate)
return NULL;
candidate = parameter;
}
}
return candidate;
}
// Find record version for relation in statement's saved record version.
static dsql_par* dsqlFindRecordVersion(const dsql_req* request, const RelationSourceNode* relation_name)
{
DEV_BLKCHK(request, dsql_type_req);
const dsql_msg* message = request->getStatement()->getReceiveMsg();
dsql_par* candidate = NULL;
const MetaName& relName = relation_name->dsqlName;
for (FB_SIZE_T i = 0; i < message->msg_parameters.getCount(); ++i)
{
dsql_par* parameter = message->msg_parameters[i];
if (parameter->par_rec_version_relname.hasData() &&
parameter->par_rec_version_relname == relName)
{
if (candidate)
return NULL;
candidate = parameter;
}
}
return candidate;
}
// Generate DML header for INSERT/UPDATE/DELETE.
static const dsql_msg* dsqlGenDmlHeader(DsqlCompilerScratch* dsqlScratch, RseNode* dsqlRse)
{
const dsql_msg* message = NULL;
const bool innerSend = !dsqlRse || (dsqlScratch->flags & DsqlCompilerScratch::FLAG_UPDATE_OR_INSERT);
const bool merge = dsqlScratch->flags & DsqlCompilerScratch::FLAG_MERGE;
if (dsqlScratch->getStatement()->getType() == DsqlCompiledStatement::TYPE_EXEC_PROCEDURE &&
!innerSend && !merge)
{
if ((message = dsqlScratch->getStatement()->getReceiveMsg()))
{
dsqlScratch->appendUChar(blr_send);
dsqlScratch->appendUChar(message->msg_number);
}
}
if (dsqlRse)
{
dsqlScratch->appendUChar(blr_for);
GEN_expr(dsqlScratch, dsqlRse);
}
if (dsqlScratch->getStatement()->getType() == DsqlCompiledStatement::TYPE_EXEC_PROCEDURE)
{
if ((message = dsqlScratch->getStatement()->getReceiveMsg()))
{
dsqlScratch->appendUChar(blr_begin);
if (innerSend && !merge)
{
dsqlScratch->appendUChar(blr_send);
dsqlScratch->appendUChar(message->msg_number);
}
}
}
return message;
}
// Get the context of a relation, procedure or derived table.
static dsql_ctx* dsqlGetContext(const RecordSourceNode* node)
{
const ProcedureSourceNode* procNode;
const RelationSourceNode* relNode;
const RseNode* rseNode;
if ((procNode = ExprNode::as<ProcedureSourceNode>(node)))
return procNode->dsqlContext;
if ((relNode = ExprNode::as<RelationSourceNode>(node)))
return relNode->dsqlContext;
if ((rseNode = ExprNode::as<RseNode>(node)))
return rseNode->dsqlContext;
fb_assert(false);
return NULL;
}
// Get the contexts of a relation, procedure, derived table or a list of joins.
static void dsqlGetContexts(DsqlContextStack& contexts, const RecordSourceNode* node)
{
const ProcedureSourceNode* procNode;
const RelationSourceNode* relNode;
const RseNode* rseNode;
if ((procNode = ExprNode::as<ProcedureSourceNode>(node)))
contexts.push(procNode->dsqlContext);
else if ((relNode = ExprNode::as<RelationSourceNode>(node)))
contexts.push(relNode->dsqlContext);
else if ((rseNode = ExprNode::as<RseNode>(node)))
{
if (rseNode->dsqlContext) // derived table
contexts.push(rseNode->dsqlContext);
else // joins
{
NestConst<RecSourceListNode> streamList = rseNode->dsqlStreams;
for (NestConst<RecordSourceNode>* ptr = streamList->items.begin();
ptr != streamList->items.end();
++ptr)
{
dsqlGetContexts(contexts, *ptr);
}
}
}
else
{
fb_assert(false);
}
}
// Create a compound statement to initialize returning parameters.
static StmtNode* dsqlNullifyReturning(DsqlCompilerScratch* dsqlScratch, StmtNode* input, bool returnList)
{
thread_db* tdbb = JRD_get_thread_data();
MemoryPool& pool = *tdbb->getDefaultPool();
StmtNode* returning = NULL;
EraseNode* eraseNode;
ModifyNode* modifyNode;
StoreNode* storeNode;
if (eraseNode = input->as<EraseNode>())
returning = eraseNode->statement;
else if (modifyNode = input->as<ModifyNode>())
returning = modifyNode->statement2;
else if (storeNode = input->as<StoreNode>())
returning = storeNode->statement2;
else
{
fb_assert(false);
}
if (dsqlScratch->isPsql() || !returning)
return returnList ? input : NULL;
// If this is a RETURNING in DSQL, we need to initialize the output
// parameters with NULL, to return in case of empty resultset.
// Note: this may be changed in the future, i.e. return empty resultset
// instead of NULLs. In this case, I suppose this function could be
// completely removed.
// nod_returning was already processed
CompoundStmtNode* returningStmt = returning->as<CompoundStmtNode>();
fb_assert(returningStmt);
CompoundStmtNode* nullAssign = FB_NEW(pool) CompoundStmtNode(pool);
NestConst<StmtNode>* ret_ptr = returningStmt->statements.begin();
NestConst<StmtNode>* null_ptr = nullAssign->statements.getBuffer(returningStmt->statements.getCount());
for (const NestConst<StmtNode>* const end = ret_ptr + returningStmt->statements.getCount();
ret_ptr != end;
++ret_ptr, ++null_ptr)
{
AssignmentNode* assign = FB_NEW(pool) AssignmentNode(pool);
assign->asgnFrom = FB_NEW(pool) NullNode(pool);
assign->asgnTo = (*ret_ptr)->as<AssignmentNode>()->asgnTo;
*null_ptr = assign;
}
// If asked for, return a compound statement with the initialization and the
// original statement.
if (returnList)
{
CompoundStmtNode* list = FB_NEW(pool) CompoundStmtNode(pool);
list->statements.add(nullAssign);
list->statements.add(input);
return list;
}
return nullAssign; // return the initialization statement.
}
// Check that a field is named only once in INSERT or UPDATE statements.
static void dsqlFieldAppearsOnce(const Array<NestConst<ValueExprNode> >& values, const char* command)
{
for (FB_SIZE_T i = 0; i < values.getCount(); ++i)
{
const FieldNode* field1 = values[i]->as<FieldNode>();
if (!field1)
continue;
const MetaName& name1 = field1->dsqlField->fld_name;
for (FB_SIZE_T j = i + 1; j < values.getCount(); ++j)
{
const FieldNode* field2 = values[j]->as<FieldNode>();
if (!field2)
continue;
const MetaName& name2 = field2->dsqlField->fld_name;
if (name1 == name2)
{
string str = field1->dsqlContext->ctx_relation->rel_name.c_str();
str += ".";
str += name1.c_str();
//// FIXME: line/column is not very accurate for MERGE ... INSERT.
ERRD_post(
Arg::Gds(isc_sqlerr) << Arg::Num(-206) <<
Arg::Gds(isc_dsql_no_dup_name) << str << command <<
Arg::Gds(isc_dsql_line_col_error) <<
Arg::Num(values[j]->line) << Arg::Num(values[j]->column));
}
}
}
}
static ValueListNode* dsqlPassArray(DsqlCompilerScratch* dsqlScratch, ValueListNode* input)
{
if (!input)
return NULL;
MemoryPool& pool = dsqlScratch->getStatement()->getPool();
ValueListNode* output = FB_NEW(pool) ValueListNode(pool, input->items.getCount());
NestConst<ValueExprNode>* ptr = input->items.begin();
NestConst<ValueExprNode>* ptr2 = output->items.begin();
for (const NestConst<ValueExprNode>* const end = input->items.end(); ptr != end; ++ptr, ++ptr2)
*ptr2 = Node::doDsqlPass(dsqlScratch, *ptr);
return output;
}
// Turn a cursor reference into a record selection expression.
static dsql_ctx* dsqlPassCursorContext(DsqlCompilerScratch* dsqlScratch, const MetaName& cursor,
const RelationSourceNode* relation_name)
{
DEV_BLKCHK(dsqlScratch, dsql_type_req);
const MetaName& relName = relation_name->dsqlName;
// this function must throw an error if no cursor was found
const DeclareCursorNode* node = PASS1_cursor_name(dsqlScratch, cursor,
DeclareCursorNode::CUR_TYPE_ALL, true);
fb_assert(node);
const RseNode* nodeRse = node->rse->as<RseNode>();
fb_assert(nodeRse);
if (nodeRse->dsqlDistinct)
{
// cursor with DISTINCT is not updatable
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-510) <<
Arg::Gds(isc_dsql_cursor_update_err) << cursor);
}
NestConst<RecSourceListNode> temp = nodeRse->dsqlStreams;
dsql_ctx* context = NULL;
NestConst<RecordSourceNode>* ptr = temp->items.begin();
for (const NestConst<RecordSourceNode>* const end = temp->items.end(); ptr != end; ++ptr)
{
RecordSourceNode* r_node = *ptr;
RelationSourceNode* relNode = ExprNode::as<RelationSourceNode>(r_node);
if (relNode)
{
dsql_ctx* candidate = relNode->dsqlContext;
DEV_BLKCHK(candidate, dsql_type_ctx);
const dsql_rel* relation = candidate->ctx_relation;
if (relation->rel_name == relName)
{
if (context)
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-504) <<
Arg::Gds(isc_dsql_cursor_err) <<
Arg::Gds(isc_dsql_cursor_rel_ambiguous) << Arg::Str(relName) <<
cursor);
}
else
context = candidate;
}
}
else if (ExprNode::as<AggregateSourceNode>(r_node))
{
// cursor with aggregation is not updatable
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-510) <<
Arg::Gds(isc_dsql_cursor_update_err) << cursor);
}
// note that UnionSourceNode and joins will cause the error below,
// as well as derived tables. Some cases deserve fixing in the future
}
if (!context)
{
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-504) <<
Arg::Gds(isc_dsql_cursor_err) <<
Arg::Gds(isc_dsql_cursor_rel_not_found) << Arg::Str(relName) << cursor);
}
return context;
}
// Turn a cursor reference into a record selection expression.
static RseNode* dsqlPassCursorReference(DsqlCompilerScratch* dsqlScratch, const MetaName& cursor,
RelationSourceNode* relation_name)
{
DEV_BLKCHK(dsqlScratch, dsql_type_req);
thread_db* tdbb = JRD_get_thread_data();
MemoryPool& pool = *tdbb->getDefaultPool();
// Lookup parent dsqlScratch
dsql_req* const* const symbol = dsqlScratch->getAttachment()->dbb_cursors.get(cursor.c_str());
if (!symbol)
{
// cursor is not found
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-504) <<
Arg::Gds(isc_dsql_cursor_err) <<
Arg::Gds(isc_dsql_cursor_not_found) << cursor);
}
dsql_req* parent = *symbol;
// Verify that the cursor is appropriate and updatable
dsql_par* source = dsqlFindDbKey(parent, relation_name);
dsql_par* rv_source = dsqlFindRecordVersion(parent, relation_name);
if (!source || !rv_source)
{
// cursor is not updatable
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-510) <<
Arg::Gds(isc_dsql_cursor_update_err) << cursor);
}
DsqlCompiledStatement* const statement = dsqlScratch->getStatement();
statement->setParentRequest(parent);
statement->setParentDbKey(source);
statement->setParentRecVersion(rv_source);
parent->cursors.add(statement);
// Build record selection expression
RseNode* rse = FB_NEW(pool) RseNode(pool);
rse->dsqlStreams = FB_NEW(pool) RecSourceListNode(pool, 1);
RelationSourceNode* relation_node =
PASS1_relation(dsqlScratch, relation_name)->as<RelationSourceNode>();
rse->dsqlStreams->items[0] = relation_node;
RecordKeyNode* dbKeyNode = FB_NEW(pool) RecordKeyNode(pool, blr_dbkey);
dbKeyNode->dsqlRelation = relation_node;
dsql_par* parameter = MAKE_parameter(statement->getSendMsg(), false, false, 0, NULL);
statement->setDbKey(parameter);
ParameterNode* paramNode = FB_NEW(pool) ParameterNode(pool);
paramNode->dsqlParameterIndex = parameter->par_index;
paramNode->dsqlParameter = parameter;
parameter->par_desc = source->par_desc;
ComparativeBoolNode* eqlNode1 =
FB_NEW(pool) ComparativeBoolNode(pool, blr_eql, dbKeyNode, paramNode);
dbKeyNode = FB_NEW(pool) RecordKeyNode(pool, blr_record_version);
dbKeyNode->dsqlRelation = relation_node;
parameter = MAKE_parameter(statement->getSendMsg(), false, false, 0, NULL);
statement->setRecVersion(parameter);
paramNode = FB_NEW(pool) ParameterNode(pool);
paramNode->dsqlParameterIndex = parameter->par_index;
paramNode->dsqlParameter = parameter;
parameter->par_desc = rv_source->par_desc;
ComparativeBoolNode* eqlNode2 =
FB_NEW(pool) ComparativeBoolNode(pool, blr_eql, dbKeyNode, paramNode);
rse->dsqlWhere = PASS1_compose(eqlNode1, eqlNode2, blr_and);
return rse;
}
// Create (if necessary) a hidden variable to store a temporary value.
static VariableNode* dsqlPassHiddenVariable(DsqlCompilerScratch* dsqlScratch, ValueExprNode* expr)
{
thread_db* tdbb = JRD_get_thread_data();
// For some node types, it's better to not create temporary value.
switch (expr->type)
{
case ExprNode::TYPE_CURRENT_DATE:
case ExprNode::TYPE_CURRENT_TIME:
case ExprNode::TYPE_CURRENT_TIMESTAMP:
case ExprNode::TYPE_CURRENT_ROLE:
case ExprNode::TYPE_CURRENT_USER:
case ExprNode::TYPE_FIELD:
case ExprNode::TYPE_INTERNAL_INFO:
case ExprNode::TYPE_LITERAL:
case ExprNode::TYPE_NULL:
case ExprNode::TYPE_PARAMETER:
case ExprNode::TYPE_RECORD_KEY:
case ExprNode::TYPE_VARIABLE:
return NULL;
}
VariableNode* varNode = FB_NEW(*tdbb->getDefaultPool()) VariableNode(*tdbb->getDefaultPool());
varNode->dsqlVar = dsqlScratch->makeVariable(NULL, "", dsql_var::TYPE_HIDDEN,
0, 0, dsqlScratch->hiddenVarsNumber++);
MAKE_desc(dsqlScratch, &varNode->dsqlVar->desc, expr);
varNode->nodDesc = varNode->dsqlVar->desc;
return varNode;
}
// Process loop interruption.
static USHORT dsqlPassLabel(DsqlCompilerScratch* dsqlScratch, bool breakContinue, MetaName* label)
{
// look for a label, if specified
USHORT position = 0;
if (label)
{
int index = dsqlScratch->loopLevel;
for (Stack<MetaName*>::iterator stack(dsqlScratch->labels); stack.hasData(); ++stack)
{
const MetaName* obj = stack.object();
if (obj && *label == *obj)
{
position = index;
break;
}
--index;
}
}
USHORT number = 0;
if (breakContinue)
{
if (position > 0)
{
// break/continue the specified loop
number = position;
}
else if (label)
{
// ERROR: Label %s is not found in the current scope
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
Arg::Gds(isc_dsql_command_err) <<
Arg::Gds(isc_dsql_invalid_label) << *label <<
Arg::Str("is not found"));
}
else
{
// break/continue the current loop
number = dsqlScratch->loopLevel;
}
}
else
{
if (position > 0)
{
// ERROR: Label %s already exists in the current scope
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
Arg::Gds(isc_dsql_command_err) <<
Arg::Gds(isc_dsql_invalid_label) << *label <<
Arg::Str("already exists"));
}
else
{
// store label name, if specified
dsqlScratch->labels.push(label);
number = dsqlScratch->loopLevel;
}
}
fb_assert(number > 0 && number <= dsqlScratch->loopLevel);
return number;
}
// Compile a RETURNING clause (nod_returning or not).
static StmtNode* dsqlProcessReturning(DsqlCompilerScratch* dsqlScratch, ReturningClause* input,
StmtNode* stmt)
{
thread_db* tdbb = JRD_get_thread_data();
if (stmt)
{
const bool isPsql = dsqlScratch->isPsql();
PsqlChanger changer(dsqlScratch, false);
stmt = stmt->dsqlPass(dsqlScratch);
if (!isPsql)
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_EXEC_PROCEDURE);
return stmt;
}
if (!input)
return NULL;
MemoryPool& pool = *tdbb->getDefaultPool();
ValueListNode* const source = Node::doDsqlPass(dsqlScratch, input->first, false);
dsqlScratch->flags |= DsqlCompilerScratch::FLAG_RETURNING_INTO;
ValueListNode* target = dsqlPassArray(dsqlScratch, input->second);
dsqlScratch->flags &= ~DsqlCompilerScratch::FLAG_RETURNING_INTO;
if (!dsqlScratch->isPsql() && target)
{
// RETURNING INTO is not allowed syntax for DSQL
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
// Token unknown
Arg::Gds(isc_token_err) <<
Arg::Gds(isc_random) << Arg::Str("INTO"));
}
else if (dsqlScratch->isPsql() && !target)
{
// This trick because we don't copy lexer positions when copying lists.
const ValueListNode* errSrc = input->first;
// RETURNING without INTO is not allowed for PSQL
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-104) <<
// Unexpected end of command
Arg::Gds(isc_command_end_err2) << Arg::Num(errSrc->line) <<
Arg::Num(errSrc->column));
}
const unsigned int count = source->items.getCount();
fb_assert(count);
CompoundStmtNode* node = FB_NEW(pool) CompoundStmtNode(pool);
if (target)
{
// PSQL case
fb_assert(dsqlScratch->isPsql());
if (count != target->items.getCount())
{
// count of column list and value list don't match
ERRD_post(Arg::Gds(isc_sqlerr) << Arg::Num(-804) <<
Arg::Gds(isc_dsql_var_count_err));
}
NestConst<ValueExprNode>* src = source->items.begin();
NestConst<ValueExprNode>* dst = target->items.begin();
for (const NestConst<ValueExprNode>* const end = source->items.end(); src != end; ++src, ++dst)
{
AssignmentNode* temp = FB_NEW(pool) AssignmentNode(pool);
temp->asgnFrom = *src;
temp->asgnTo = *dst;
node->statements.add(temp);
}
}
else
{
// DSQL case
fb_assert(!dsqlScratch->isPsql());
NestConst<ValueExprNode>* src = source->items.begin();
for (const NestConst<ValueExprNode>* const end = source->items.end(); src != end; ++src)
{
dsql_par* parameter = MAKE_parameter(dsqlScratch->getStatement()->getReceiveMsg(),
true, true, 0, *src);
parameter->par_node = *src;
MAKE_desc(dsqlScratch, &parameter->par_desc, *src);
parameter->par_desc.dsc_flags |= DSC_nullable;
ParameterNode* paramNode = FB_NEW(*tdbb->getDefaultPool()) ParameterNode(
*tdbb->getDefaultPool());
paramNode->dsqlParameterIndex = parameter->par_index;
paramNode->dsqlParameter = parameter;
AssignmentNode* temp = FB_NEW(pool) AssignmentNode(pool);
temp->asgnFrom = *src;
temp->asgnTo = paramNode;
node->statements.add(temp);
}
}
if (!dsqlScratch->isPsql())
dsqlScratch->getStatement()->setType(DsqlCompiledStatement::TYPE_EXEC_PROCEDURE);
return node;
}
// Setup parameter name.
// This function was added as a part of array data type support for InterClient. It is called when
// either "insert" or "update" statements are parsed. If the statements have input parameters, then
// the parameter is assigned the name of the field it is being inserted (or updated). The same goes
// to the name of a relation.
// The names are assigned to the parameter only if the field is of array data type.
static void dsqlSetParameterName(ExprNode* exprNode, const ValueExprNode* fld_node,
const dsql_rel* relation)
{
DEV_BLKCHK(fld_node, dsql_type_nod);
DEV_BLKCHK(relation, dsql_type_dsql_rel);
if (!exprNode)
return;
const FieldNode* fieldNode = ExprNode::as<FieldNode>(fld_node);
fb_assert(fieldNode); // Could it be something else ???
if (fieldNode->nodDesc.dsc_dtype != dtype_array)
return;
switch (exprNode->type)
{
case ExprNode::TYPE_ARITHMETIC:
case ExprNode::TYPE_CONCATENATE:
case ExprNode::TYPE_EXTRACT:
case ExprNode::TYPE_NEGATE:
case ExprNode::TYPE_STR_CASE:
case ExprNode::TYPE_STR_LEN:
case ExprNode::TYPE_SUBSTRING:
case ExprNode::TYPE_SUBSTRING_SIMILAR:
case ExprNode::TYPE_TRIM:
for (NodeRef** i = exprNode->dsqlChildNodes.begin(); i != exprNode->dsqlChildNodes.end(); ++i)
dsqlSetParameterName((*i)->getExpr(), fld_node, relation);
break;
case ExprNode::TYPE_PARAMETER:
{
ParameterNode* paramNode = exprNode->as<ParameterNode>();
dsql_par* parameter = paramNode->dsqlParameter;
parameter->par_name = fieldNode->dsqlField->fld_name.c_str();
parameter->par_rel_name = relation->rel_name.c_str();
break;
}
}
}
// Setup parameter parameters name.
static void dsqlSetParametersName(CompoundStmtNode* statements, const RecordSourceNode* relNode)
{
const dsql_ctx* context = relNode->dsqlContext;
DEV_BLKCHK(context, dsql_type_ctx);
const dsql_rel* relation = context->ctx_relation;
FB_SIZE_T count = statements->statements.getCount();
NestConst<StmtNode>* ptr = statements->statements.begin();
for (NestConst<StmtNode>* const end = ptr + count; ptr != end; ++ptr)
{
AssignmentNode* assign = (*ptr)->as<AssignmentNode>();
if (assign)
dsqlSetParameterName(assign->asgnFrom, assign->asgnTo, relation);
else
{
fb_assert(false);
}
}
}
// Perform cleaning of rpb, zeroing unassigned fields and the impure tail of varying fields that
// we don't want to carry when the RLE algorithm is applied.
static void cleanupRpb(thread_db* tdbb, record_param* rpb)
{
Record* const record = rpb->rpb_record;
const Format* const format = record->getFormat();
SET_TDBB(tdbb); // Is it necessary?
/*
Starting from the format, walk through its
array of descriptors. If the descriptor has
no address, its a computed field and we shouldn't
try to fix it. Get a pointer to the actual data
and see if that field is null by indexing into
the null flags between the record header and the
record data.
*/
for (USHORT n = 0; n < format->fmt_count; n++)
{
const dsc* desc = &format->fmt_desc[n];
if (!desc->dsc_address)
continue;
UCHAR* const p = record->getData() + (IPTR) desc->dsc_address;
if (record->isNull(n))
{
USHORT length = desc->dsc_length;
if (length)
memset(p, 0, length);
}
else if (desc->dsc_dtype == dtype_varying)
{
vary* varying = reinterpret_cast<vary*>(p);
USHORT length = desc->dsc_length - sizeof(USHORT);
if (length > varying->vary_length)
{
char* trail = varying->vary_string + varying->vary_length;
length -= varying->vary_length;
memset(trail, 0, length);
}
}
}
}
// Build a validation list for a relation, if appropriate.
static void makeValidation(thread_db* tdbb, CompilerScratch* csb, StreamType stream,
Array<ValidateInfo>& validations)
{
SET_TDBB(tdbb);
DEV_BLKCHK(csb, type_csb);
jrd_rel* relation = csb->csb_rpt[stream].csb_relation;
vec<jrd_fld*>* vector = relation->rel_fields;
if (!vector)
return;
//StreamType local_map[JrdStatement::MAP_LENGTH];
AutoPtr<StreamType, ArrayDelete<StreamType> > localMap;
StreamType* map = csb->csb_rpt[stream].csb_map;
if (!map)
{
localMap = FB_NEW(*tdbb->getDefaultPool()) StreamType[STREAM_MAP_LENGTH];
map = localMap;
fb_assert(stream <= MAX_STREAMS); // CVC: MAX_UCHAR still relevant for the bitmap?
map[0] = stream;
}
USHORT fieldId = 0;
vec<jrd_fld*>::iterator ptr1 = vector->begin();
for (const vec<jrd_fld*>::const_iterator end = vector->end(); ptr1 < end; ++ptr1, ++fieldId)
{
BoolExprNode* validation;
if (*ptr1 && (validation = (*ptr1)->fld_validation))
{
AutoSetRestore<USHORT> autoRemapVariable(&csb->csb_remap_variable,
(csb->csb_variables ? csb->csb_variables->count() : 0) + 1);
RemapFieldNodeCopier copier(csb, map, fieldId);
validation = copier.copy(tdbb, validation);
ValidateInfo validate;
validate.boolean = validation;
validate.value = PAR_gen_field(tdbb, stream, fieldId);
validations.add(validate);
}
if (*ptr1 && (validation = (*ptr1)->fld_not_null))
{
AutoSetRestore<USHORT> autoRemapVariable(&csb->csb_remap_variable,
(csb->csb_variables ? csb->csb_variables->count() : 0) + 1);
RemapFieldNodeCopier copier(csb, map, fieldId);
validation = copier.copy(tdbb, validation);
ValidateInfo validate;
validate.boolean = validation;
validate.value = PAR_gen_field(tdbb, stream, fieldId);
validations.add(validate);
}
}
}
// Process a view update performed by a trigger.
static StmtNode* pass1ExpandView(thread_db* tdbb, CompilerScratch* csb, StreamType orgStream,
StreamType newStream, bool remap)
{
SET_TDBB(tdbb);
DEV_BLKCHK(csb, type_csb);
StmtNodeStack stack;
jrd_rel* relation = csb->csb_rpt[orgStream].csb_relation;
vec<jrd_fld*>* fields = relation->rel_fields;
dsc desc;
USHORT id = 0, newId = 0;
vec<jrd_fld*>::iterator ptr = fields->begin();
for (const vec<jrd_fld*>::const_iterator end = fields->end(); ptr < end; ++ptr, ++id)
{
if (*ptr)
{
if (remap)
{
const jrd_fld* field = MET_get_field(relation, id);
if (field->fld_source)
newId = field->fld_source->as<FieldNode>()->fieldId;
else
newId = id;
}
else
newId = id;
const Format* const format = CMP_format(tdbb, csb, newStream);
if (newId >= format->fmt_count || !format->fmt_desc[newId].dsc_address)
continue;
AssignmentNode* const assign =
FB_NEW(*tdbb->getDefaultPool()) AssignmentNode(*tdbb->getDefaultPool());
assign->asgnTo = PAR_gen_field(tdbb, newStream, newId);
assign->asgnFrom = PAR_gen_field(tdbb, orgStream, id);
stack.push(assign);
}
}
return PAR_make_list(tdbb, stack);
}
// Check out a prospective update to a relation. If it fails security check, bounce it.
// If it's a view update, make sure the view is updatable, and return the view source for redirection.
// If it's a simple relation, return NULL.
static RelationSourceNode* pass1Update(thread_db* tdbb, CompilerScratch* csb, jrd_rel* relation,
const trig_vec* trigger, StreamType stream, StreamType updateStream, SecurityClass::flags_t priv,
jrd_rel* view, StreamType viewStream, StreamType viewUpdateStream)
{
SET_TDBB(tdbb);
DEV_BLKCHK(csb, type_csb);
DEV_BLKCHK(relation, type_rel);
DEV_BLKCHK(view, type_rel);
// unless this is an internal request, check access permission
CMP_post_access(tdbb, csb, relation->rel_security_name, (view ? view->rel_id : 0),
priv, SCL_object_table, relation->rel_name);
// ensure that the view is set for the input streams,
// so that access to views can be checked at the field level
fb_assert(viewStream <= MAX_STREAMS);
CMP_csb_element(csb, stream)->csb_view = view;
CMP_csb_element(csb, stream)->csb_view_stream = viewStream;
if (stream != updateStream)
{
fb_assert(viewUpdateStream <= MAX_STREAMS);
CMP_csb_element(csb, updateStream)->csb_view = view;
CMP_csb_element(csb, updateStream)->csb_view_stream = viewUpdateStream;
}
// if we're not a view, everything's cool
RseNode* rse = relation->rel_view_rse;
if (!rse)
return NULL;
// a view with triggers is always updatable
if (trigger)
{
bool userTriggers = false;
for (FB_SIZE_T i = 0; i < trigger->getCount(); i++)
{
if (!(*trigger)[i].sys_trigger)
{
userTriggers = true;
break;
}
}
if (userTriggers)
{
csb->csb_rpt[updateStream].csb_flags |= csb_view_update;
return NULL;
}
}
// we've got a view without triggers, let's check whether it's updateable
if (rse->rse_relations.getCount() != 1 || rse->rse_projection || rse->rse_sorted ||
rse->rse_relations[0]->type != RelationSourceNode::TYPE)
{
ERR_post(Arg::Gds(isc_read_only_view) << Arg::Str(relation->rel_name));
}
// for an updateable view, return the view source
csb->csb_rpt[updateStream].csb_flags |= csb_view_update;
return static_cast<RelationSourceNode*>(rse->rse_relations[0].getObject());
}
// The csb->csb_validate_expr becomes true if an ancestor of the current node (the one being
// passed in) in the parse tree is a validation. "Ancestor" does not include the current node
// being passed in as an argument.
// If we are in a "validate subtree" (as determined by the csb->csb_validate_expr), we must not
// post update access to the fields involved in the validation clause.
// (See the call for CMP_post_access in this function.)
static void pass1Validations(thread_db* tdbb, CompilerScratch* csb, Array<ValidateInfo>& validations)
{
AutoSetRestore<bool> autoValidateExpr(&csb->csb_validate_expr, true);
for (Array<ValidateInfo>::iterator i = validations.begin(); i != validations.end(); ++i)
{
DmlNode::doPass1(tdbb, csb, i->boolean.getAddress());
DmlNode::doPass1(tdbb, csb, i->value.getAddress());
}
}
// Inherit access to triggers to be fired.
//
// When we detect that a trigger could be fired by a request,
// then we add the access list for that trigger to the access
// list for this request. That way, when we check access for
// the request we also check access for any other objects that
// could be fired off by the request.
//
// Note that when we add the access item, we specify that
// Trigger X needs access to resource Y.
// In the access list we parse here, if there is no "accessor"
// name then the trigger must access it directly. If there is
// an "accessor" name, then something accessed by this trigger
// must require the access.
//
// CVC: The code no longer matches this comment.
// CVC: The third parameter is the owner of the triggers vector
// and was added to avoid triggers posting access checks to
// their base tables, since it's nonsense and causes weird
// messages about false REFERENCES right failures.
static void postTriggerAccess(CompilerScratch* csb, jrd_rel* ownerRelation,
ExternalAccess::exa_act operation, jrd_rel* view)
{
DEV_BLKCHK(csb, type_csb);
DEV_BLKCHK(view, type_rel);
// allow all access to internal requests
if (csb->csb_g_flags & (csb_internal | csb_ignore_perm))
return;
// Post trigger access
ExternalAccess temp(operation, ownerRelation->rel_id, view ? view->rel_id : 0);
FB_SIZE_T i;
if (!csb->csb_external.find(temp, i))
csb->csb_external.insert(i, temp);
}
// Perform operation's pre-triggers, storing active rpb in chain.
static void preModifyEraseTriggers(thread_db* tdbb, trig_vec** trigs,
StmtNode::WhichTrigger whichTrig, record_param* rpb, record_param* rec, TriggerAction op)
{
if (!tdbb->getTransaction()->tra_rpblist)
{
tdbb->getTransaction()->tra_rpblist =
FB_NEW(*tdbb->getTransaction()->tra_pool) traRpbList(*tdbb->getTransaction()->tra_pool);
}
const int rpblevel = tdbb->getTransaction()->tra_rpblist->PushRpb(rpb);
if (*trigs && whichTrig != StmtNode::POST_TRIG)
{
try
{
EXE_execute_triggers(tdbb, trigs, rpb, rec, op, StmtNode::PRE_TRIG);
}
catch (const Exception&)
{
tdbb->getTransaction()->tra_rpblist->PopRpb(rpb, rpblevel);
throw;
}
}
tdbb->getTransaction()->tra_rpblist->PopRpb(rpb, rpblevel);
}
// Execute a list of validation expressions.
static void validateExpressions(thread_db* tdbb, const Array<ValidateInfo>& validations)
{
SET_TDBB(tdbb);
Array<ValidateInfo>::const_iterator end = validations.end();
for (Array<ValidateInfo>::const_iterator i = validations.begin(); i != end; ++i)
{
jrd_req* request = tdbb->getRequest();
if (!i->boolean->execute(tdbb, request) && !(request->req_flags & req_null))
{
// Validation error -- report result
const char* value;
VaryStr<128> temp;
const dsc* desc = EVL_expr(tdbb, request, i->value);
const USHORT length = (desc && !(request->req_flags & req_null)) ?
MOV_make_string(desc, ttype_dynamic, &value, &temp, sizeof(temp) - 1) : 0;
if (!desc || (request->req_flags & req_null))
value = NULL_STRING_MARK;
else if (!length)
value = "";
else
const_cast<char*>(value)[length] = 0; // safe cast - data is actually on the stack
string name;
const FieldNode* fieldNode = i->value->as<FieldNode>();
if (fieldNode)
{
const jrd_rel* relation = request->req_rpb[fieldNode->fieldStream].rpb_relation;
const vec<jrd_fld*>* vector = relation->rel_fields;
const jrd_fld* field;
if (vector && fieldNode->fieldId < vector->count() &&
(field = (*vector)[fieldNode->fieldId]))
{
if (!relation->rel_name.isEmpty())
name.printf("\"%s\".\"%s\"", relation->rel_name.c_str(), field->fld_name.c_str());
else
name.printf("\"%s\"", field->fld_name.c_str());
}
}
if (name.isEmpty())
name = UNKNOWN_STRING_MARK;
ERR_post(Arg::Gds(isc_not_valid) << Arg::Str(name) << Arg::Str(value));
}
}
}
} // namespace Jrd
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