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I have the following tables in a relational database:

[Sensor]
LocationId [PK / FK -> Location]
SensorNo [PK]

[AnalogSensor]
LocationId [PK/FK -> Sensor]
SensorNo [PK/FK -> Sensor]
UpperLimit
LowerLimit

[SwitchSensor]
LocationId [PK/FK -> Sensor]
SensorNo [PK/FK -> Sensor]
OnTimeLimit

[Reading]
LocationId [PK/FK -> Sensor]
SensorNo [PK/FK -> Sensor]
ReadingDtm [PK]

[ReadingSwitch]
LocationId [PK/FK -> Reading]
SensorNo [PK/FK -> Reading]
ReadingDtm [PK/FK -> Reading]
Switch

[ReadingValue]
LocationId [PK/FK -> Reading]
SensorNo [PK/FK -> Reading]
ReadingDtm [PK/FK -> Reading]
Value

[Alert]
LocationId [PK/FK -> Reading]
SensorNo [PK/FK -> Reading]
ReadingDtm [PK/FK -> Reading]

Basically, ReadingSwitch and ReadingValue are subtypes of Reading and SwitchSensor and AnalogSensor are subtypes of Sensor. A reading can either be a SwitchReading or ValueReading value - it cannot be both, and a Sensor can either be an AnalogSensor or a SwitchSensor.

The only way I've come across to do this so far is here.

There surely must be a nicer way to do this sort of thing.

The only other way I can think of is to not have sub types but completely expand everything:

[SwitchSensor]
LocationId [PK/FK -> Location]
SensorNo [PK]

[AnalogSensor]
LocationId [PK/FK -> Location]
SensorNo [PK]

[SwitchReading]
LocationId [PK/FK -> SwitchSensor]
SensorNo [PK/FK -> SwitchSensor]
ReadingDtm
Switch

[AnalogReading]
LocationId [PK/FK -> AnalogSensor]
SensorNo [PK/FK -> AnalogSensor]
ReadingDtm
Value

[AnalogReadingAlert]
LocationId [PK/FK -> AnalogReading]
SensorNo [PK/FK -> AnalogReading]
ReadingDtm [PK/FK -> AnalogReading]

[SwitchReadingAlert]
LocationId [PK/FK -> SwitchReading]
SensorNo [PK/FK -> SwitchReading]
ReadingDtm [PK/FK -> SwitchReading]

Which might not be so bad but I also have tables that reference the Alert table, so they too would have to be duplicated:

[AnalogReadingAlertAcknowledgement]
...
[AnalogReadingAlertAction]
...
[SwitchReadingAlartAcknowledgement]
...
[SwitchReadingAlartAction]

etc.

Does this problem make any sense to anyone??

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2 Answers 2

up vote 15 down vote accepted

None of that is necessary, especially not doubling up the tables.

Introduction

Since the Standard for Modelling Relational Databases (IDEF1X) has been in common use for over 25 years (at least in the high quality, high performance end of the market), I use that terminology. Darwen, despite the great work he has done to progress the Relation Model, was unaware of IDEF1X until I brought it to his attention last year, and thus has a new terminology for the Standard terminology that we have been using for decades. Further, the new terminology does not deal with all the cases, as IDEF1X does. Therefore I use the established Standard terminology, and avoid new terminology.

  • even the concept of a "distributed key" fails to recognise the underlying ordinary PK::FK Relations, their iimplementation in SQL, and their power.

  • The Relational, and therefore IDEF1X, concept is Identifiers and Migration thereof.

  • Sure, the vendors are not exactly on the ball, and they have weird things such a "partial Indices" etc, which are completely unnecessary when the basics are understood. But famous academics coming up with incomplete new concepts when the concept was standardised and give full treatment 25 years ago ... that, is unexpected.

Caveat

IEC/ISO/ANSI SQL barely handles 5NF adequately, and it does not support Supertype-Subtype structures at all; there are no Declarative Constraints for this (and there should be).

  • Therefore , in order to enforce the full set of Rules expressed in the Data Model, both SuperType::Subtype and Subtype::Supertype, we have to fiddle a little with CHECK Constraints, etc (I avoid using Triggers for a number of reasons).

Relief

However, I take all that into account. In order for me to effectively provide a Data Modelling service on StackOverflow, without having to preface that with a full discourse, I purposely provide models that can be implemented by capable people, using existing SQL and existing Constraints, to whatever extent they require. It is already simplified, and contains the common level of enforcement. If there is any question, just ask, and you shall receive.

We can use both the example graphic in the linked document and your fully IDEF1X-compliant ▶Sensor Data Model◀

Readers who are not familiar with the Relational Modelling Standard may find ▶IDEF1X Notation◀ useful. Readers who think a database can be mapped to objects, classes, and subclasses are advised that reading further may cause injury. This is further than Fowler and Ambler have read.

Implementation of Referential Integrity for Supertype-Subtype

There are two types of Supertype-Subtype structures:

Exclusive Subtype

Exclusive means there can be only one Subtype row for each Supertype row. In IDEF1X terms, there should be a Discriminator column in the Supertype, which identifies the Supertype row and which Subtype row exists for it.

  • For more than two Subtypes, this is demanded, and I implement a Discriminator column.

  • For two Subtypes, since this is easily derived from existing data (eg. Sensor.IsSwitch is the Discriminator for Reading), I do not model an additional explicit Discriminator column for Reading. However, you are free to follow the Standard to the letter and implement a Discriminator.

I will take each aspect in detail.

  1. The Discriminator column needs a CHECK Constraint to ensure it is within the range of values, eg: IN ("B", "C", "D"). IsSwitch is a BIT, which is 0 or 1, so that is already constrained.

  2. Since the PK of the Supertype defines its uniqueness, only one Supertype row will be allowed; no second Supertype row (and thus no second Subtype row) can be inserted.

    • Therefore it is overkill, completely redundant, an additional unnecessary Index, to implement an Index such as (PK, Discriminator) in the Supertype, as your link advises. The uniqueness is in the PK, and therefore the PK plus anything will be unique).

    • IDEF1X does not require the Discriminator in the Subtype tables. In the Subtype, which is again constrained by the uniqueness of its PK, as per the model, if the Discriminator was implemented as a column in that table, every row in it will have the same value for the Discriminator (every Book will be "B"; every ReadingSwitch will be an IsSwitch). Therefore it is absurd to implement the Discriminator as a column in the Subtype. And again, completely redundant, an additional unnecessary Index, to implement an Index such as (PK, Discriminator) in the Subtype: the uniqueness is in the PK, and therefore the PK plus anything will be unique).

    • The method identified in the link is a hamfisted and bloated (massive data duplication for no purpose) way of implementing Referential Integrity. There is probably a good reason the author has not seen that construct anywhere else. It is a basic failure to understand SQL and to use it as it is effectively. These "solutions" are typical of people who follow a dogma "SQL can't do ..." and thus are blind to what SQL can do. The horrors that result from Fowler and Ambler's blind "methods" are even worse.

  3. The Subtype PK is also the FK to the Supertype, that is all that is required, to ensure that the Subtype does not exist without a parent Supertype.

    • Therefore for any given PK, whichever Supertype-Subtype is inserted first will succeed; and whichever Supertype-Subtype is attempted after that, will fail. Therefore there is nothing to worry about in the Subtype table (a second Supertype row or a second Subtype row for the same PK is prevented).
      .
  4. The SQL CHECK Constraint is limited to checking the inserted row. We need to check the inserted row against other rows, either in the same table, or in another table. Therefore a User Defined Function is required.

    • Write a simple UDF that will check for existence of the PK and the Discriminator in the SuperType, and return 1 if EXISTS or 0 if NOT EXISTS. You will need one UDF per Supertype (not per Subtype).

    • In the Subtype, implement a CHECK Constraint that calls the UDF, using the PK (which is both the Supertype and the Subtype) and the Discriminator value.

    • I have implemented this in scores of large, real world databases, on different SQL platforms. Here is the ▶User Defined Function Code◀, and the ▶DDL Code◀ for the objects it is based on.

    • This particular syntax and code is tested on Sybase ASE 15.0.2 (they are very conservative about SQL Standards compliance).

    • I am aware that the limitations on User Defined Functions are different for every SQL platform. However, this is the simplest of the simple, and AFAIK every platform allows this construct. (No idea what the Non-SQLs do.)

    • yes, of course this clever little technique can be used implement any non-trivial data rule that you can draw in a Data Model. In particular, to overcome the limitations of SQL. Note my caution to avoid two-way Constraints (circular references).

  5. Therefore the CHECK Constraint in the Subtype, ensures that the PK plus the correct Discriminator exists in Supertype. Which means that only that Subtype exists for the Supertype (the PK).

    • Any subsequent attempt to insert another Subtype (ie. break the Exclusive Rule) will fail because the PK+Discriminator does not exist in the Supertype.

    • Any subsequen attempt to insert another row of the same Subtype is prevented by the uniqueness of its PK Constraint.

  6. The only bit that is missing (not mentioned in the link) is the Rule "every Supertype must have at least one Subtype" is not enforced. This is easily covered in Transactional code (I do not advise Constraints going in two directions, or Triggers); use the right tool for the job.

Non-exclusive Subtype

The Supertype (parent) can host more than one Subtype (child)

  1. There is no one Subtype to be identified.

    • The Discriminator does not apply to Non-exclusive Subtypes.

    • The existence of a Subtype is identified by performing an existence check on the Subtype table, using the Supertype PK.

  2. Simply exclude the CHECK Constraint that calls the UDF above.

    • The PRIMARY KEY, FOREIGN KEY, and the usual Range CHECK Constraints, adequately support all requirements for Non-exclusive Subtypes.
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1  
@PerformanceDBA: PS thanks for the great answer, makes sense and I've just about got it working in PostgreSQL - just need to tweak the ValidateExclusive function (PostgreSQL has no ISNULL function). –  Mark Feb 4 '11 at 15:22
1  
@Mark. My pleasure, as always, and thanks. Improved formatting & clarity in the Answer. 1) Analog/Sitch Sensor. It is worth it to handle optional columns properly and thus avoid Nulls. Would you like an updated DM ? No charge ;-} 2) Use COALESCE(). –  PerformanceDBA Feb 4 '11 at 23:18
2  
"This is further than Fowler and Ambler have read" -- it's funny 'cos it's true! –  onedaywhen Feb 7 '11 at 7:07
1  
@onedaywhen. Oh dear. In that case, you must think that (a) one additional column plus one additional index per Subtype, plus (b) one additional index in the Supertype, with (c) their consequent overhead, and (d) the impeded inserts/deletes (each of which now have two additional indices), is equal to or better than the absence of (a)(b)(c)(d). The UDF+CHECK and the PK+FK REFERENCE are equivalent, and excluded. In which case you are operating on opinion, not on the laws of physics or computer science. In which case I would not try to convince you of anything relating to them. –  PerformanceDBA Feb 8 '11 at 15:57
3  
I've noticed that this approach doesn't prevent someone from using UPDATE to change a supertype's discriminator value. How could that be prevented? The foreign key + duplicate discriminator column in subtypes approach seems to overcome this. –  Sam Jul 22 '13 at 23:38

The second option is also fraught with issues - e.g. for Sensors (and assuming that SensorNo is a surrogate key), because you don't have a base table, the SensorNo surrogate is either not unique between the sub class tables, unless you use a klugey mechanism to issue keys across all the sub-class tables (or use a guid).

This would be amplified if you had user interface which 'combines' different types of sensors, e.g. a list showing a union of Analog and Switch sensors.

I would recommend that you stay with your first pattern, and then encapsulate the insertion and maintenance of these tables with well tested, transactional code.

e.g. Create Insertion Procedures for the various SubTables, which insert the respective base and subclass records under a unit of work. You can go further by then revoking INSERT privileges on ANY of the tables thus forcing insertion via the SPROC's.

You could also run a daily integrity report which checked that there were no violations of your inheritance structure.

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This is a Relational database, not a bunch of object classes/subclasses. Despite what Fowlers states, there are important differences. Agree with your points re security. –  PerformanceDBA Feb 4 '11 at 13:32

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