CA1208803A - Method for checking storage protection and a circuit for carrying out the same - Google Patents

Abstract

METHOD FOR CHECKING STORAGE PROTECTION AND
A CIRCUIT FOR CARRYING OUT THE SAME

ABSTRACT OF THE DISCLOSURE

A storage-protection- check circuit includes a storage key corresponding to the unit area of a storage region and being stored in a key storage. The value of the access request key having an access request corre-sponding to the storage region is checked. When the access request key has a specified value, the storage region is accessed without reading the storage key out of the key storage.

Description

lZ~B~C?3 METHOD FOR CHECKING STORAGE PROTECTION AND
A CIRCUIT FOR CARRYING OUT THE SAME

BACKGROUND OF THE INVENTION
Field of the Invention The present invention relates to a method for checking storage protection in a system providing a storage-protection key in each unit area.
Description of the Prior Art The criteria in a method for checking storage--protection is well known in "I~M*System/370 Principles of Operation" (GA 22-7000 6 File No. 370-01). That is, a main storage device is divided into a plurality of pages as a unit of storage protection, for example, into two-kilobyte blocks, and storage keys having eight bits are written into a key storage. The storage keys have the following construction:

A F R C S
In the above construction, A denotes an access control bit, F denotes a read protection bit, R denotes a reference bit, C denotes a change bit, and S denotes a write protection bit. A central processing unit or a channel provides a protection key. The central processing unit provides a protection key in program--status worcls (PSW) and a storage key in translation look aside buffers (TL~). The channel reads the channel-address words (CAW) and maintains the pro-~ tection key writtën into the CAW. The following table `~ gives a summary of the protecting action.

* Trademark ;.
,~ ,~ . .
,t~;

~2U88(~3

2 --Table Condition Is access to main storage possible?
Bit position in storage key Key relation Read Store Bit 7 (S) Bit 4 (F) O coin~;~P~t pos~ihl~pO~;hl~
O incoincident posslhlP ;m~oss;h 1 co;~ P~t poss;hle poss;hl~
1 ; nco; nci~nt lm~s~;hle ;~s~; hle O co;n~ nt poss;hl~ ;mr~sq;hle O ; n~ol n~i~Pnt possible ;mr~; hl cG;n~ Pn~e ~Q.s.s;hlP ;~:;hlP
;n~oln~i~nt ;mr~ss;hlP ;mr~;hl~

In the table, "coincidence" indicates that the pro-tection key is equal to the upper four bits or that the value of the protection key is zero. "Possible"
indicates that access is possible and "not possible"
indicates that access is not possible~ That is, when information is read out of the main storage, the information can not be used in the program, and when information is written into the main storage, the position of the storage is not changed. The write signal transmitted to the main storage is accepted when the storage key and the protection key coincide and the write protection bit of the storage key is zero. The read signal transmitted from the main storage is accepted when the storage key and the protection key coincide or the write protection bit of the storage key is zero.
However, in such conventional criteria, the time during which the next key memory access request is ~88~3 awaited becomes long and the key memory cannot be efficiently accessed.
SUMMARY OF THE INVENTION
An object of the present invention is to provide a method for checking memory protection by which memory protection of an access request to the main storage can be rapidly checked.
In accordance with one embodiment of the present inven-tion, there is providad a method for checking storage protec-tion in which a storage key corresponding to a unit area of a storage region is provided for each unit area of a main storage and the storage key is stored in a key storage, the key storage is accessed prior to the access of the main storage by an access request to the main storage and the checking storage pro-tection determines whether the main storage can be accessed or not by comparing the value of the key read out from the key storage and the value of the key included in the access re-~uest, comprising prechecking whether the value of the key included in the access request i9 a specified value which is previously determined or not, and when it is the specified value, immediately effecting the access to the main ~torage without reading the storage key out of the key storage.

lZ~88~3 - 3a -In accordance with another embodiment of the present inven-tion, there is provided a storage-protection-check circuit com-prising: an access control circuit which receives an access request from a channel, a main storage control circuit and a storage-protection key control circuit which are controlled by the access control circuit, a main storage which is controlled by the main storage control circuit, a key storage which is con-trolled by the storage-protection key control circuit; and a storage-protection-check circuit which receives an access request key from the channel, a key storage check signal from the storage-protection key control circuit, and a storage key from the key storage and outputs a main storage access admis-sion signal to the access control circuit, the storage-protection-check circuit comprising a zero check circuit which receives the access request, a coincidence check circuit which receives the access request and the storage key from the key storage, a first AND circuit which receives the output of the zero check circuit and a key storage - 4 - lZ~8~3 access request from the access control circuit, a second AND circuit which receives via a NOT circuit the output of the zero check circuit and the key storage access request and outputs a key storage access admis-sion signal to the storage-protection key control circuit, a third AND circuit which receives the output of the coincidence check circuit and the key storage check signal from the storage-protection key control circuit, and an OR circuit which receives the outputs of the first AND circuit and the second AND circuit and outputs the main storage access admission signal to the access control circuit.
Further features and advantages of the present invention will be apparent from the ensuing description, with reference to the accompanying drawings, to which, however, the scope of the invention is in no way limited.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram illustrating one example of a conventional storage-protection-check circuit. ~
Figure 2 is a flow chart lllustrating the operation of the circuit shown in Fig. l.
Figure 3 is a block diagram illustrating one embodiment of the storage-protection-check circuit according to the present invention.
Fi~ure 4 is a flow chart illustrating the operation of the circuit shown in Fig. 3.
DESCRIPTION OF THE PREFERRED EM~ODIMENTS
Figure 1 shows a conventional storage-protection--check circuit. In the figure 1 denotes an access control circuit, 2 denotes a main storage control circuit, 3 denotes a storage-protection key control circuit, 4 denotes a storage-protection-check circuit, 5 denotes a main storage~ 6 denotes a key storage, 10 denotes an access request, 11 denotes an access request key, 12 denotes a main storage access request t 13 ~2~8803 denotes a key storage access request, 20 denotes a line which transmits main storage access information, 30 denotes a line which transmits key storage access information, 31 denotes a key storage check signal, 40 s denotes a main storage access admission signal, 42 denotes a zero check signal, 43 denotes a coincidence signal, Z denotes a zero check circuit, M denotes a coincidence check circuit, O denotes an OR circuit, and A denotes an AND circuit.
The access control circuit 1 analyzes the access request and controls the main storage control circuit 2 and the storage-protection key control circuit 3 in accordance with the result of analysis. The main storage control circuit 2 controls the main storage S, and the storage-protection key control circuit 3 controls the key storage 6. The storage-protection--check circuit 4 includes the zero check circuit Z, the coincidence check circuit M, the OR circuit O, and the AND circuit A. The zero check circuit Z determines whether or not the access request key 11 is zero, and the coincidence check circuit M determines whether or not the access request key 11 and the storage key 60 read from the key storage 6 are coincident. The access request key 11 includes both protection key information and read/write information. When zero check signal 42 is logic "1" or the coincidence signal 43 i.s logic "1", the OR circuit 0 outputs logic "1". When the key storage check signal 31 becomes logic "1" when the OR
circuit "0" outputs logic "1", the main storage access admission signal 40 becomes logic "1". The key storage check signal 31 is output at a suitable time when data i5 read out of the key storage 6.
When the channel accesses to the main storage via a block barrier of pages, the channel sends an access request having a key check to the access control circuit 1. Further, since the central processing unit reads the storage key into the TLB before receiving - 6 - ~2~8~3 this access request, the central processing unit checks whether a request for main storage access is possible or not. When the access control circuit 1 receives the access request having a key check, the access control S circuit 1 sends the key storage access request 13 1:o the storage-protection key control circuit 3. When the storage-projection key control circuit 3 receives the key storage access request 13, it sends the key storage access information 30 to the key storage 6. The key storage access information 30 includes a read/write signal indicating read or write and key storage address information. In this case, the read/write signal indicates read. The storage key 60 which is read out of the key storage 6 is sent to the coincidence check lS circuit M in the storage-protection-check circuit 4.
If the zero check signal 42 or the coincidence signal 43 is logic "1" when the storage-protection key control circuit 3 sends the key storage check signal 31, the value of which is logic "1", the main storage access admission signal 40 becomes logic "1". When the main storage access admission signal 40 becomes logic "1", the access control circuit 1 sends the main storage access request 12 to the main storage control circuit 2.
When the main strage control circuit 2 receives the main storage access request 12, the main stroage control circuit 2 sends the main storage access infor-mation 20 ta, the main storage 5. The main storage 5 effects read/write in accordance with the main storage access information 20.
Figure 2 is a flow chart illustrating the operation of the circuit shown in Fig. 1. In the circuit, it is checked whether or not an a~cess request from the channel (block 513 has a key storage (block 52). If it has a key storage, the key storage is read (block 53), and it is checked in block 54 whether or not the access request key is zero. If the access request key is not zero, it is checked in block 55 whether or not the read - 7 ~ 12~ 3 key is coincident with the access request. If the read key is coincident with the access request, the main storage is accessed in block 56 and the result of access is sent to the channel in block 57. If the read key is not coincident with the access request, a key check is impossible.
When the access request key has a specified value, main storage access is possible regardless of the data read out of the key storage. However, in the conven-tional system shown in Fig. 1, even if the accessrequest key has a specified value, the main memory access admission signal may be logic "1" when the storage check signal becomes logic "1". In such a conventional system, the time during which the ne~t key memory access request is awaited becomes long and the key memory cannot be efficiently accessed.
Next, the invention is explained with reference to Fig. 3, which illustrates one embodiment of the present invention. In Fig. 3, Al to A3 denote AND circuit, N
denotes an NOT circuit, and 41 denotes a key storage access admission signal. The other elements in Fig. 3 are the same as the elements in Fig. l and are repre-sented by the same reference numerals as in Fig. l.
The storage-protection-check circuit 4 shown in Fig. 3 includes a zero check circuit 2, a coincidence check circuit M, the NOT circuit N, the AND circuits A
to A3 , and an OR circuit 0. The AND circuit Al receives a zero check signal 42 and a key storage access request 13, and the AND circuit A3-rece~ves a coincidence signal 43 and a key storage check signal 31.
The outputs of the AND circuits Al and A3 are supplied to the input of the OR circuit 0, and the output of the OR circuit 0 is used as a main storage access admission signal 40. The AND circuit A2 receives the key storage access request 13 and an inverted signal of the zexo check signal 42. The output of the AND circuit A2 becomes the key storage access admission signal 41.

- 8 _ 12~ 3 Next, the operation of the embodiment shown in Fig. 3 is explained. When the channel accesses, via the block barrier, a main storage 5, the channel sends an access request 10 having a key check and an access request key 11 to an access control circuit 1. When the access control circuit 1 receives the access request 10 having a key check, the access control circuit 1 sends the key storage access request 13 to the AND circuits Al and A2. On the other hand, the access request key 11 is supplied to the zero check circuit Z. If the zero check signal 42 is logic "1"
when the key storage access request 13 is sent to the AND circuits Al and A2 ~ the main storage access admission signal 40 becomes logic "1". When the main storage access admission signal 40 becomes logic "1", the access control circuit 1 controls so as to carry out main storage access. If the zero check signal 42 is logic "0" when the key storage access request 13 is sent to the AND circuits Al and A2 ~ the key storage access admission signal 41 is sent to a storage--protection key control circuit 3. When the storage--protection key control circuit 3 receives the key storage access admission signal 41, the circuit 3 sends key storage access information 30 to a key storage 6.
A storag,e key 60, which is read out of the key storage 6, is supplied to the coincidence check circuit M in the storage-protlection-check circuit 4~ When the storage--protection key control circuit 3 turns the key storage check signal 31 on, the coincidence signal 43 is sent ~ia the AND circuit A3 and the OR circuit 0 to the access control circuit 1 so that the main storage access admission signal 40 is sent to the access control circuit 1. When the main storage access admission signal 40 is logic "1", the access control circuit 1 controls so as to carry out main storage access.
Figure 4 is a flow ch~rt illustrating the operation - 9 - 12~ 3 of the circuit shown in Fig. 3. In Fig. 4, blocks 51a to 59a correspond to blocks 51 to 59 in Fig. 2. The feature of Fig. 4 differs from that of Fig. 2 in that the order of blocks 53a and 54a is reversed. That is, the value of the access request key having an access request i5 checked in block 54a, and when the value of the access request key is zero, the main storage is accessed in block 56a.
As should be clear from the above explanation, according to the present invention, if the access request key has a specified value, the main storage can be accessed without accessing the key storage. There-fore, accessing of the key storage can be efficiently carried out.

Claims (2)

The embodiments of the invention in which an exclu-sive property or privilege is claimed are defined as follows:

1. A method for checking storage protection in which a storage key corresponding to a unit area of a storage region is provided for each unit area of a main storage and said storage key is stored in a key storage, the key storage is accessed prior to the access of the main storage by an access request to said main storage and said checking storage protection deter-mines whether the main storage can be accessed or not by compar-ing the value of the key read out from said key storage and the value of the key included in said access request, comprising prechecking whether the value of said key included in the access request is a specified value which is previously deter-mined or not, and when it is the specified value, immediately effecting the access to said main storage without reading said storage key out of said key storage.

2. A storage-protection-check circuit comprising: an access control circuit which receives an access request from a channel, a main storage control circuit and a storage-protection key control circuit which are controlled by said access control circuit, a main storage which is controlled by said main storage control circuit, a key storage which is con-trolled by said storage-protection key control circuit; and a storage-protection-check circuit which receives an access request key from the channel, a key storage check signal from said storage-protection key control circuit, and a storage key from said key storage and outputs a main storage access admis-sion signal to said access control circuit, said storage-protection-check circuit comprising a zero check circuit which receives said access request, a coincidence check circuit which receives said access request and said storage key from said key storage, a first AND circuit which receives the output of said zero check circuit and a key storage access request from said access control circuit, a second AND circuit which receives via an NOT circuit the output of said zero check circuit and said key storage access request, and outputs a key storage access admission signal to said storage-protection key control cir-cuit, a third AND circuit which receives the outputs of said coincidence check circuit and said key storage check signal from said storage-protection key control circuit, and an OR cir-cuit which receives the outputs of said first AND circuit and said second AND circuit and outputs said main storage access admission signal to said access control circuit.