public async Task <(List <DynamicRow> result, IEnumerable <TreeDimensionResult> trees)> ToListAsync(CancellationToken cancellation)
{
var queryArgs = await _factory(cancellation);
var conn = queryArgs.Connection;
var sources = queryArgs.Sources;
var userId = queryArgs.UserId;
var userToday = queryArgs.UserToday;
var localizer = queryArgs.Localizer;
var logger = queryArgs.Logger;
// ------------------------ Validation Step
// SELECT Validation
if (_select == null)
{
string message = $"The select argument is required";
throw new InvalidOperationException(message);
}
// Make sure that measures are well formed: every column access is wrapped inside an aggregation function
foreach (var exp in _select)
{
if (exp.ContainsAggregations) // This is a measure
{
// Every column access must descend from an aggregation function
var exposedColumnAccess = exp.UnaggregatedColumnAccesses().FirstOrDefault();
if (exposedColumnAccess != null)
{
throw new QueryException($"Select parameter contains a measure with a column access {exposedColumnAccess} that is not included within an aggregation.");
}
}
}
// ORDER BY Validation
if (_orderby != null)
{
foreach (var exp in _orderby)
{
// Order by cannot be a constant
if (!exp.ContainsAggregations && !exp.ContainsColumnAccesses)
{
throw new QueryException("OrderBy parameter cannot be a constant, every orderby expression must contain either an aggregation or a column access.");
}
}
}
// FILTER Validation
if (_filter != null)
{
var conditionWithAggregation = _filter.Expression.Aggregations().FirstOrDefault();
if (conditionWithAggregation != null)
{
throw new QueryException($"Filter contains a condition with an aggregation function: {conditionWithAggregation}");
}
}
// HAVING Validation
if (_having != null)
{
// Every column access must descend from an aggregation function
var exposedColumnAccess = _having.Expression.UnaggregatedColumnAccesses().FirstOrDefault();
if (exposedColumnAccess != null)
{
throw new QueryException($"Having parameter contains a column access {exposedColumnAccess} that is not included within an aggregation.");
}
}
// ------------------------ Preparation Step
// If all is good Prepare some universal variables and parameters
var vars = new SqlStatementVariables();
var ps = new SqlStatementParameters();
var today = userToday ?? DateTime.Today;
var now = DateTimeOffset.Now;
// ------------------------ Tree Analysis Step
// By convention if A.B.Id AND A.B.ParentId are both in the select expression,
// then this is a tree dimension and we return all the ancestors of A.B,
// What do we select for the ancestors? All non-aggregated expressions in
// the original select that contain column accesses exclusively starting with A.B
var additionalNodeSelects = new List <QueryexColumnAccess>();
var ancestorsStatements = new List <DimensionAncestorsStatement>();
{
// Find all column access atoms that terminate with ParentId, those are the potential tree dimensions
var parentIdSelects = _select
.Where(e => e is QueryexColumnAccess ca && ca.Property == "ParentId")
.Cast <QueryexColumnAccess>();
foreach (var parentIdSelect in parentIdSelects)
{
var pathToTreeEntity = parentIdSelect.Path; // A.B
// Confirm it's a tree dimension
var idSelect = _select.FirstOrDefault(e => e is QueryexColumnAccess ca && ca.Property == "Id" && ca.PathEquals(pathToTreeEntity));
if (idSelect != null)
{
// Prepare the Join Trie
var treeType = TypeDescriptor.Get <T>();
foreach (var step in pathToTreeEntity)
{
treeType = treeType.NavigationProperty(step)?.TypeDescriptor ??
throw new QueryException($"Property {step} does not exist on type {treeType.Name}.");
}
// Create or Get the name of the Node column
string nodeColumnName = NodeColumnName(additionalNodeSelects.Count);
additionalNodeSelects.Add(new QueryexColumnAccess(pathToTreeEntity, "Node")); // Tell the principal query to include this node
// Get all atoms that contain column accesses exclusively starting with A.B
var principalSelectsWithMatchingPrefix = _select
.Where(exp => exp.ColumnAccesses().All(ca => ca.PathStartsWith(pathToTreeEntity)));
// Calculate the target indices
var targetIndices = principalSelectsWithMatchingPrefix
.Select(exp => SelectIndexDictionary[exp]);
// Remove the prefix from all column accesses
var ancestorSelects = principalSelectsWithMatchingPrefix
.Select(exp => exp.Clone(prefixToRemove: pathToTreeEntity));
var allPaths = ancestorSelects.SelectMany(e => e.ColumnAccesses()).Select(e => e.Path);
var joinTrie = JoinTrie.Make(treeType, allPaths);
var joinSql = joinTrie.GetSql(sources, fromSql: null);
// Prepare the Context
var ctx = new QxCompilationContext(joinTrie, sources, vars, ps, today, now, userId);
// Prepare the SQL components
var selectSql = PrepareAncestorSelectSql(ctx, ancestorSelects);
var principalQuerySql = PreparePrincipalQuerySql(nodeColumnName);
// Combine the SQL components
string sql = QueryTools.CombineSql(
selectSql: selectSql,
joinSql: joinSql,
principalQuerySql: principalQuerySql,
whereSql: null,
orderbySql: null,
offsetFetchSql: null,
groupbySql: null,
havingSql: null,
selectFromTempSql: null);
// Get the index of the id select
int idIndex = SelectIndexDictionary[idSelect];
// Create and add the statement object
var statement = new DimensionAncestorsStatement(idIndex, sql, targetIndices);
ancestorsStatements.Add(statement);
}
}
}
// ------------------------ The SQL Generation Step
// (1) Prepare the JOIN's clause
var principalJoinTrie = PreparePrincipalJoin();
var principalJoinSql = principalJoinTrie.GetSql(sources, fromSql: null);
// Compilation context
var principalCtx = new QxCompilationContext(principalJoinTrie, sources, vars, ps, today, now, userId);
// (2) Prepare all the SQL clauses
var(principalSelectSql, principalGroupbySql, principalColumnCount) = PreparePrincipalSelectAndGroupBySql(principalCtx, additionalNodeSelects);
string principalWhereSql = PreparePrincipalWhereSql(principalCtx);
string principalHavingSql = PreparePrincipalHavingSql(principalCtx);
string principalOrderbySql = PreparePrincipalOrderBySql();
string principalSelectFromTempSql = PrepareSelectFromTempSql();
// (3) Put together the final SQL statement and return it
string principalSql = QueryTools.CombineSql(
selectSql: principalSelectSql,
joinSql: principalJoinSql,
principalQuerySql: null,
whereSql: principalWhereSql,
orderbySql: principalOrderbySql,
offsetFetchSql: null,
groupbySql: principalGroupbySql,
havingSql: principalHavingSql,
selectFromTempSql: principalSelectFromTempSql
);
// ------------------------ Execute SQL and return Result
var principalStatement = new SqlDynamicStatement(principalSql, principalColumnCount);
var(result, trees, _) = await EntityLoader.LoadDynamicStatement(
principalStatement : principalStatement,
dimAncestorsStatements : ancestorsStatements,
includeCount : false,
vars : vars,
ps : ps,
conn : conn,
logger : logger,
cancellation : cancellation);
return(result, trees);
}
/// <summary>
/// This methods loads the results of an <see cref="AggregateQuery{T}"/> into a list of <see cref="DynamicRow"/>
/// </summary>
/// <param name="principalStatement">The principal <see cref="SqlStatement"/> to load first.</param>
/// <param name="preparatorySql">Any SQL to be included at the very beginning the main script (cannot contain a SELECT or return a result set</param>
/// <param name="ps">The parameters needed by SQL</param>
/// <param name="conn">The SQL Server connection through which to execute the SQL script</param>
/// <returns>The list of hydrated <see cref="DynamicRow"/>s</returns>
public static async Task <(List <DynamicRow> result, IEnumerable <TreeDimensionResult> treeDimensions, int count)> LoadDynamicStatement(
SqlDynamicStatement principalStatement,
IEnumerable <DimensionAncestorsStatement> dimAncestorsStatements,
bool includeCount,
SqlStatementVariables vars,
SqlStatementParameters ps,
SqlConnection conn,
ILogger logger,
CancellationToken cancellation)
{
dimAncestorsStatements ??= new List <DimensionAncestorsStatement>();
var result = new List <DynamicRow>();
var treeResults = new List <TreeDimensionResult>();
int count = 0;
////////////// Prepare the complete SQL code
// Add any variables in the preparatory SQL
string variablesSql = vars.ToSql();
var statements = new List <string>(1 + dimAncestorsStatements.Count())
{
principalStatement.Sql
};
statements.AddRange(dimAncestorsStatements.Select(e => e.Sql));
string sql = PrepareSql(variablesSql, null, null, statements.ToArray());
using (var cmd = conn.CreateCommand())
{
// Command Text
cmd.CommandText = sql;
// Command Parameters
foreach (var parameter in ps)
{
cmd.Parameters.Add(parameter);
}
// It will always be open, but we add this nonetheless for robustness
bool ownsConnection = conn.State != System.Data.ConnectionState.Open;
if (ownsConnection)
{
conn.Open();
}
// Results are loaded
try
{
// Load results of the principal query
using var reader = await cmd.ExecuteReaderAsync(cancellation);
{
int columnCount = principalStatement.ColumnCount;
while (await reader.ReadAsync(cancellation))
{
var row = new DynamicRow(columnCount);
for (int index = 0; index < columnCount; index++)
{
var dbValue = reader[index];
if (dbValue == DBNull.Value)
{
dbValue = null;
}
row.Add(dbValue);
}
result.Add(row);
}
}
// Load the tree dimensions
foreach (var treeStatement in dimAncestorsStatements)
{
int columnCount = treeStatement.TargetIndices.Count();
int index;
int minIndex = treeStatement.TargetIndices.Min();
int[] targetIndices = treeStatement.TargetIndices.Select(i => i - minIndex).ToArray();
var treeResult = new TreeDimensionResult(treeStatement.IdIndex, minIndex);
await reader.NextResultAsync(cancellation);
while (await reader.ReadAsync(cancellation))
{
var row = new DynamicRow(columnCount);
for (index = 0; index < targetIndices.Length; index++)
{
int targetIndex = targetIndices[index];
var dbValue = reader[index];
if (dbValue == DBNull.Value)
{
dbValue = null;
}
row.AddAt(dbValue, targetIndex);
}
treeResult.Result.Add(row);
}
treeResults.Add(treeResult);
}
// Load the count if any
if (includeCount)
{
await reader.NextResultAsync(cancellation);
if (await reader.ReadAsync(cancellation))
{
count = reader.GetInt32(0);
}
}
}
catch (SqlException ex) when(ex.Number is 8134) // Divide by zero
{
throw new QueryException(DIVISION_BY_ZERO_MESSAGE);
}
catch (SqlException ex)
{
logger.LogError(ex, FullSqlForLogger(sql, ps)); // Log the generated SQL code for debugging
throw;
}
finally
{
// Otherwise we might get an error when a parameter is reused
cmd.Parameters.Clear();
// The connection is never owned, but we add this code anyways for robustness
if (ownsConnection)
{
conn.Close();
conn.Dispose();
}
}
}
return(result, treeResults, count);
}
private async Task <(List <DynamicRow>, int count)> ToListAndCountInnerAsync(bool includeCount, int maxCount, CancellationToken cancellation)
{
var queryArgs = await _factory(cancellation);
var conn = queryArgs.Connection;
var sources = queryArgs.Sources;
var userId = queryArgs.UserId;
var userToday = queryArgs.UserToday;
var localizer = queryArgs.Localizer;
var logger = queryArgs.Logger;
// ------------------------ Validation Step
// SELECT Validation
if (_select == null)
{
string message = $"The select argument is required";
throw new InvalidOperationException(message);
}
// Make sure that measures are well formed: every column access is wrapped inside an aggregation function
foreach (var exp in _select)
{
var aggregation = exp.Aggregations().FirstOrDefault();
if (aggregation != null)
{
throw new QueryException($"Select cannot contain an aggregation function like: {aggregation.Name}");
}
}
// ORDER BY Validation
if (_orderby != null)
{
foreach (var exp in _orderby)
{
// Order by cannot be a constant
if (!exp.ContainsAggregations && !exp.ContainsColumnAccesses)
{
throw new QueryException("OrderBy parameter cannot be a constant, every orderby expression must contain either an aggregation or a column access.");
}
}
}
// FILTER Validation
if (_filter != null)
{
var conditionWithAggregation = _filter.Expression.Aggregations().FirstOrDefault();
if (conditionWithAggregation != null)
{
throw new QueryException($"Filter contains a condition with an aggregation function: {conditionWithAggregation}");
}
}
// ------------------------ Preparation Step
// If all is good Prepare some universal variables and parameters
var vars = new SqlStatementVariables();
var ps = new SqlStatementParameters();
var today = userToday ?? DateTime.Today;
var now = DateTimeOffset.Now;
// ------------------------ The SQL Generation Step
// (1) Prepare the JOIN's clause
var joinTrie = PrepareJoin();
var joinSql = joinTrie.GetSql(sources, fromSql: null);
// Compilation context
var ctx = new QxCompilationContext(joinTrie, sources, vars, ps, today, now, userId);
// (2) Prepare all the SQL clauses
var(selectSql, columnCount) = PrepareSelectSql(ctx);
string whereSql = PrepareWhereSql(ctx);
string orderbySql = PrepareOrderBySql(ctx);
string offsetFetchSql = PrepareOffsetFetch();
// (3) Put together the final SQL statement and return it
string sql = QueryTools.CombineSql(
selectSql: selectSql,
joinSql: joinSql,
principalQuerySql: null,
whereSql: whereSql,
orderbySql: orderbySql,
offsetFetchSql: offsetFetchSql,
groupbySql: null,
havingSql: null,
selectFromTempSql: null
);
// ------------------------ Prepare the Count SQL
if (includeCount)
{
string countSelectSql = maxCount > 0 ? $"SELECT TOP {maxCount} [P].*" : "SELECT [P].*";
string countSql = QueryTools.CombineSql(
selectSql: countSelectSql,
joinSql: joinSql,
principalQuerySql: null,
whereSql: whereSql,
orderbySql: null,
offsetFetchSql: null,
groupbySql: null,
havingSql: null,
selectFromTempSql: null
);
sql = $@"
{sql}
SELECT COUNT(*) As [Count] FROM (
{QueryTools.IndentLines(countSql)}
) AS [Q]";
}
// ------------------------ Execute SQL and return Result
var principalStatement = new SqlDynamicStatement(sql, columnCount);
var(result, _, count) = await EntityLoader.LoadDynamicStatement(
principalStatement : principalStatement,
dimAncestorsStatements : null,
includeCount,
vars : vars,
ps : ps,
conn : conn,
logger : logger,
cancellation : cancellation);
return(result, count);
}
