JP2001109699A - Data transmitter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suitably distribute the amount of data to be transmitted to the respective transmission destinations at the time of parallel transmitting the data to the plural transmission destinations. SOLUTION: The data stored in a data transfer buffer 112 of a memory control unit 100 are successively transmitted from a connecting port 108 to transfer destination connecting ports 1011, 1012 and 1013. A transmission buffer controller 109 distributes the area of a data transfer buffer 112 for storing the data to the transfer destination connecting ports 1011, 1012 and 1013 corresponding to the data transfer rate of a path to the transfer destination connecting ports 1011, 1012 and 1013. Since a lot of data transmission quantities are applied to the path capable of transmitting a lot of data and a little data transmission quantity is applied to the path disabled in the transmission of a lot of data, the stagnation of a frame in a buffer in the middle of the path or occurrence of play in the data transfer ability of the path can be suppressed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission apparatus, and more particularly, to appropriately allocating a data transmission amount to each destination when transmitting data to a plurality of destinations in parallel. The present invention relates to a data transmission device capable of performing the following.

[0002]

2. Description of the Related Art As a protocol for a data transmitting apparatus to transmit data to a plurality of destinations in parallel, there is known a frame multiplexing protocol for transmitting a frame to each destination in order. In other words, this is a system in which a frame for another destination is inserted between frames for a certain destination. An example of the frame multiplexing protocol is a fiber channel protocol. For more information on Fiber Channel standards, see “Fib
re Channel Physical and Signaling Interface ”,
Revision 4.3, American National Standard for I
nformation Systems: ANSI (1994) ".

When connecting remote devices, a general public line or a network may be interposed. In this case, if the protocol of both devices is different from the protocol of the general public line or network, a converter is connected to the end of the port of both devices, and the protocol is converted for communication. In this way, the substantial data transfer rate in the case of performing protocol conversion by the converter and performing communication is not the data transfer rate of both devices but the minimum data transfer rate in the path.

[0004]

Conventionally, when data is transmitted by a frame multiplexing protocol, a data transmitting apparatus
Data is transmitted in the order from the earliest request from each transmission destination. However, since the frequency of requests from each destination does not correspond to the value of the substantial data transfer rate, the data transmission device needs to send unnecessarily large data to the destination of the path having the low data transfer rate. In some cases, the transmission amount is given, or the data transmission rate is given too small to the destination of a path having a high data transfer rate.

That is, in the conventional data transmitting apparatus, when data is transmitted in parallel to a plurality of destinations, there is a problem that the distribution of the data transmission amount to each destination is not always appropriate. Therefore, an object of the present invention is to provide a data transmission device capable of appropriately allocating a data transmission amount to each transmission destination when transmitting data to a plurality of transmission destinations in parallel.

[0006]

According to a first aspect of the present invention, when data is transmitted to each of a plurality of destinations, a predetermined data unit is sequentially transmitted to the plurality of destinations. A data transmission unit, a transfer rate input unit for inputting a data transfer rate of each path to the plurality of destinations, and a transmission rate input unit for transmitting data to each of the plurality of destinations. A data transmission device comprising: a data transmission rate control means for controlling a data transmission rate in sequence according to the data transfer rate. In the data transmitting apparatus according to the first aspect, the trigger for transmitting a predetermined data unit, that is, the data transmission amount is controlled in accordance with the data transfer rate of the path to each destination. That is, a large data transmission amount is given to a path through which a large amount of data can be transmitted, and a small data transmission amount is given to a path through which a large amount of data cannot be transmitted. Therefore, the amount of data transmission to each transmission destination can be appropriately allocated, and it is possible to suppress accumulation of frames in a buffer in the middle of a path and occurrence of play in the data transfer capability of the path.

[0007] In a second aspect, the present invention provides a data transmission means for transmitting data to each of a plurality of destinations by a predetermined data unit in order to the plurality of destinations, Data transfer rate calculating means for measuring an average number of I / Os per unit time and an average data length of each path to a plurality of transmission destinations and obtaining a data transfer rate of each path based on the measurement result; When transmitting data to each of the transmission destinations, a transmission timing control means for controlling a transmission timing of a predetermined data unit in order to the plurality of transmission destinations in accordance with the data transfer rate. A feature is provided of a data transmission device. In the data transmitting apparatus according to the second aspect, the trigger for transmitting a predetermined data unit at a time, that is, the amount of data transmission is controlled according to the data transfer rate of the path to each destination. That is, a large data transmission amount is given to a path through which a large amount of data can be transmitted, and a small data transmission amount is given to a path through which a large amount of data cannot be transmitted. Therefore, the amount of data transmission to each transmission destination can be appropriately allocated, and it is possible to suppress accumulation of frames in a buffer in the middle of a path and occurrence of play in the data transfer capability of the path. Further, the average number of I / Os per unit time and the average data length are measured, and the data transfer rate is obtained from the measurement result. Therefore, even if the data transfer rate fluctuates for some reason, data transmission to each destination is performed. We can distribute quantity appropriately.

[0008] In a third aspect, the present invention provides the data transmission device according to the first or second aspect, wherein the transmission trigger control means sets a ratio of a trigger for transmitting a predetermined data unit to each destination. Is controlled based on the ratio of the data transfer rate corresponding to each destination. In the data transmitting apparatus according to the third aspect, the trigger for transmitting a predetermined data unit at a time, that is, the ratio of the data transmission amount is controlled according to the ratio of the data transfer rate of the path to each destination. That is, a data transmission amount proportional to the data transfer capability of the path is given. Therefore, the amount of data transmission to each transmission destination can be appropriately allocated, and it is possible to suppress accumulation of frames in a buffer in the middle of a path and occurrence of play in the data transfer capability of the path.

In a fourth aspect, the present invention provides the data transmission apparatus according to the third aspect, wherein the transmission trigger control means transmits a predetermined data unit to a transmission destination having a low data transfer rate. A data transmission device is provided, wherein the ratio is higher than the ratio of the data transfer rate corresponding to the destination. In the data transmitting apparatus according to the fourth aspect, the timing of transmitting a predetermined data unit at a time, that is, the ratio of the data transmission amount is controlled according to the ratio of the data transfer rate of the path to each destination. The data transmission amount given to the low transmission destination is slightly higher than the data transmission amount proportional to the data transfer capability of the path. As a result, it is possible to prevent the amount of data transmission given to destinations having a low data transfer rate from becoming too small, and to appropriately distribute the amount of data transmission to each destination.

According to a fifth aspect, the present invention provides a data transmitting means for transmitting data to a plurality of destinations by a predetermined data unit sequentially to the plurality of destinations, Priority storing means for storing respective priorities of a plurality of destinations, and transmitting data to the plurality of destinations in order by a predetermined data unit when transmitting data to each of the plurality of destinations There is provided a data transmission device comprising: a transmission timing control unit that controls a timing in accordance with the priority. In the data transmitting apparatus according to the fifth aspect, the trigger for transmitting a predetermined data unit, that is, the data transmission amount is controlled in accordance with the priority of each transmission destination. That is, the amount of data transmission to each destination can be freely allocated by setting the priority. Therefore, for example, if the priority is set based on the data transfer capability of the path to each destination, the amount of data transmission can be distributed according to the data transfer capability of the path to each destination.

The data transmitting apparatus of the present invention is an apparatus for transmitting data to a plurality of destinations in parallel,
For example, a storage controller that transfers data to a plurality of central processing units, a central processing unit that transfers data to a plurality of storage controllers, or a device that transfers data to a plurality of storage controllers. It includes a storage controller to be duplicated.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. Note that the present invention is not limited by this.

-First Embodiment- The first embodiment is an embodiment in which the amount of transmission data is distributed in proportion to the data transfer rate of a path to a transfer destination.

FIG. 1 is a configuration diagram of a storage subsystem according to the first embodiment of the present invention. The storage subsystem 1 includes central processing units 101, 102, and 103, and a storage control device 100. The storage control device 10
0 indicates the drive 105 and the service processor 106
And the remote console 107 are connected. The service processor 107 and the remote console 108 are used to operate the storage controller 100 from outside.

The connection port 10 of the central processing unit 101
11 is a converter 1021, a line 1030 and a converter 102
2 and the dynamic switch 104, and connected to the connection port 108 of the storage controller 100.
The connection port 1012 of the central processing unit 102 is connected to the storage controller 1 via a dynamic switch 104.
00 is connected to the connection port 108. A connection port 1013 of the central processing unit 103 is connected to a connection port 108 of the storage control device 100 via a dynamic switch 104. As an example of the dynamic switch 104, in the fiber protocol, there is an exchange called a fabric.

The substantial data transfer rate between the connection port 1011 and the connection port 108 depends on the converter 10
21 and the converter 1022, the connection port 1012 and the connection port 108
Between the data transfer rate and the connection port 1013
And the data transfer rate between the connection port 108 and the connection port 108 is different. The connection port 108 is connected to each connection port 1
011, 1012, and 1013 by frame multiplexing.

The storage controller 100 includes a data transfer buffer 112 for transmitting and receiving data, a transmission buffer controller 109 for controlling data transmission, a reception / command controller 113 for receiving data and controlling commands from the host. , A drive controller 111 for controlling the drive 105, a cache memory 115 for temporarily storing data from the drive 105,
Intermediate buffer 114 and data transfer request flag 117
And a transfer rate storage table 116.

FIG. 2 shows the transfer rate storage table 11.
6 is a configuration diagram of the data transfer request flag 117 and the intermediate buffer 114. Transfer rate storage table 116, for each destination connection port, the data transfer path to the destination connection Portrait a _n, priority, average I /
The number k _{n of} Os and the average data length l _n are managed. The data transfer rate a _n and the priority can be input from the service processor 106 and remote console 107.
The average number of I / O k _n and the average data length l _n are updated by the measurement in the storage control device 100. Intermediate buffer 11
4 exists corresponding to each transfer destination connection port. The data transfer request flag 117 exists corresponding to each intermediate buffer 114, becomes “1” when data enters the corresponding intermediate buffer 114, and becomes “1” when data moves from the corresponding intermediate buffer 114 to the data transfer buffer 112. 0 ".

FIG. 3 shows the transmission buffer controller 109.
FIG. 6 is a flowchart showing a control procedure of data transfer of FIG. In step 301, the transmission buffer controller 109 checks whether “1” is set in any of the data transfer request flags 117, and proceeds to step 302 if any of the data transfer request flags 117 is set. On the other hand, the reception / command controller 110 has the transfer destination connection ports 1011, 1012, 1
013, the data transfer buffer 112 receives the data transfer request, transfers the data to be transferred in response to the data transfer request from the cache memory 115 or the drive 105 to the intermediate buffer 114, and sets the corresponding data transfer request flag 117 To "1".

In step 302, calculation of the allocated amount of the data transfer buffer 112 is started. That is, when the minimum value of the data transfer in the rates a _n paths to the destination connection port with a data transfer request and a _min, quota b _n [plane] of the data transfer buffer for each destination connection port, It is determined by b _n = a _n / a _min . For example, the connection port 1011 of FIG.
When there is a data transfer request from 1012 or 1013, the data transfer rates a ₁ , a ₂ and a of the path to the transfer destination connection port
₃ is 100 MB / s, 100 MB / s, 5 MB / s, so the minimum value a _min is 5 MB / s, and
The assigned amounts b ₁ , b ₂ , and b ₃ for the connection ports 1011, 1012, and 1013 are as follows: b ₁ = 100/5 = 20 [face] b ₂ = 100/5 = 20 [face] b ₃ = 5/5 = 1 [Surface]

In step 303, the value of the transfer destination connection port number counter i is initialized to "1". Step 30
In step 4, it is checked whether the value of the transfer destination connection port number counter i exceeds the number of transfer destination connection ports connected to the connection port 108. If not, the process proceeds to step 305, and if it does, the process returns to step 301. .

In step 305, it is checked whether or not the quota of the data transfer buffer 112 for the i-th transfer destination connection port exists.
Go to step 6; if not, go to step 309.
In step 306, it is checked whether "1" is set in the data transfer request flag 117 corresponding to the i-th transfer destination connection port. If "1" is set, the process proceeds to step 307; Proceed to 309. In step 307, data is transferred by one plane from the intermediate buffer 114 corresponding to the i-th transfer destination connection port to the allocated area of the data transfer buffer 112. Intermediate buffer 11
When the data of No. 4 is transferred to the assigned area of the data transfer buffer 112 by one plane, the data is transmitted to the i-th transfer destination connection port by one plane. In step 308, the allocation amount of the data transfer buffer 112 to the i-th transfer destination connection port is deleted by one. Then, the process returns to step 305.

In step 309, the value of the transfer destination connection port number counter i is increased by "1", and
Return to 04.

According to the first embodiment, the transmission data amount can be distributed in proportion to the data transfer rate of the path to the transfer destination connection port. Therefore, a large amount of data is transmitted on a path having a high data transfer rate (a path through which a large amount of data can be transmitted), and a small amount of data is transmitted on a path having a low data transfer rate (a path through which a large amount of data cannot be transmitted). In addition, it is possible to suppress accumulation of frames in a buffer in the middle of a path or occurrence of play in the data transfer capability of the path.

Second Embodiment In the second embodiment, the transmission data amount is basically controlled in accordance with the data transfer rate of the path to the transfer destination connection port as in the first embodiment. This is an embodiment in which the amount of transmission data of a path having a low data transfer rate is not reduced.

FIG. 4 is a flowchart showing the calculation process of the data transfer buffer allocation amount (step 302 in FIG. 3). In step 401, the transfer destination connection ports that the data transfer request, rearranged in order of the low data rate a _n paths. Moreover, obtain the minimum value a _min in the data transfer rate a _n paths to the destination connection port with a data transfer request. In addition, the number of transfer destination connection ports for which a data transfer request is made is M. Further, the value of the remaining number counter N is initialized to M. In step 402, assuming that the data transfer rate of the connection port 108 is C, the upper limit b _max [plane] of the allocated amount is obtained by the following equation. b _max = C / a _{min In} step 403, the value of the transfer destination connection port order counter i is initialized to “1”.

In step 404, the upper limit b _{max of the} quota
It is checked whether ≧ 0, and if b _max ≧ 0, the process proceeds to step 405, and if b _max <0, the process proceeds to step 408. Step 4
At 051, when the minimum data transfer rate in the path to the i-th transfer destination connection port is a _i , the allocated amount Ri [plane] of the data transfer buffer 112 for the i-th transfer destination connection port is determined by the following equation. . In the step 4052, Ri = a _i / a _min , the upper limit b of the allocation amount by the allocation amount Ri.
Decrease _max . In b _max = b _max -Ri step 406, to minimize "1" to the remaining number counter N. In step 407, the value of the transfer destination connection port order counter i is increased by "1". Then, the process returns to step 404. By the steps 404 to 407,
Until quota limit b _max is negative, the data transfer path to the destination connection ports that the data transfer request rate a _n
The data transfer buffers 112 are allocated in ascending order.

[0028] At step 408, the data from those data transfer rate a _n paths to the destination connection ports that the data transfer request is low until i th sequentially transfer buffer 112
Are assigned, but the data transfer buffer 112 is returned to the assigned state up to the (i-1) th. That is, i, b _max , and N are returned to the previous state. Step 4
In step 10, if the value of the transfer destination connection port order counter i is smaller than or equal to the number M of transfer destination connection ports having a data transfer request, the process proceeds to step 411, and if larger, the process ends. In step 411, the data transfer buffer 11
The unallocated amount b _max of 2 divided by the remaining number counter N is
It is assumed that the data transfer buffer 112 is allocated to the i-th transfer destination connection port. When a decimal point appears in the assigned amount, the decimal portion is appropriately processed by rounding up, rounding down, rounding off, etc., and converting the assigned amount to an integer. In step 412, the value of the transfer destination connection port order counter i is increased by "1". Then, the process returns to step 410.

For example, the connection ports 1011 and 10 shown in FIG.
When there is a data transfer request from the transfer destination connection ports 12 and 1013, the data transfer rates a ₁ , a ₂ and a
₃ is 100 MB / s, 100 MB / s, and 5 MB / s, so the ports are rearranged in the order of the connection ports 1013, 1011 and 1012. The minimum value a _min is 5 MB / s, and the data transfer rate C of the connection port 108 is set to 100M.
B / s, the initial value of the upper limit b _max of the quota is 20
[Face]. Then, first, the data transfer rate a _n
Because There is assigned 1 [surface] with respect to the lowest connection port 1013, then b _max is negative where the data transfer rate a _n is the next lowest connection port 1011 is 20 [surface] assigned, It is returned to the remaining 19 [surfaces], and this is allocated to the remaining connection ports 1011 and 1012 on an average basis. Thus, the connection ports 1011 and 1012 have 9.5 [surfaces] each. 10 [surface] is assigned to 1011 and connection port 10
12 is assigned 9 [planes].

According to the second embodiment described above, when the difference between a path having a low data transfer rate and a path having a high data transfer rate is large, the amount of data allocated to a path having a low data transfer rate, that is, the amount of transmission data, becomes too small. Can be avoided.

Third Embodiment In the third embodiment, the transmission data amount is controlled in accordance with the data transfer rate of the path to the transfer destination connection port, as in the first embodiment and the second embodiment. Suruga, the data transfer rate, rather than externally applied, which is an embodiment of the storage control device 100 is determined using the average number of I / O k _n per unit measured time and the average data length l _n.

The received command controller 110 each time it receives a data transfer request, the average number of I / O k _n and the average data length l _n per unit time of the transfer rate storage table 116 and a time and the data transfer request Update. Then, a data transfer rate a _n paths to the destination connection port by the following equation. Then _{a n = k n * l n} , using the data transfer rate a _n calculated in this calculation, as in the first embodiment and the second embodiment, to control the quota i.e. the amount of data transmitted.

According to the third embodiment, even if the data transfer rate fluctuates for some reason, the amount of data transmission to each destination can be appropriately allocated.

-Fourth Embodiment- A fourth embodiment is basically the same as the first and second embodiments, but uses a priority instead of a data transfer rate to transmit. This is an embodiment for controlling the data amount.

That is, the priority given from the outside is used in place of the data transfer rate, and the first embodiment and the second embodiment are used.
In the same manner as in the first embodiment, the allocation amount, that is, the transmission data amount is controlled.

According to the fourth embodiment, the amount of data transmitted to each destination can be freely allocated.

-Other Embodiments- The first to fourth embodiments are embodiments in which the present invention is provided to the storage subsystem 1, but the present invention is similarly applied to the central processing units 101 to 103. Can also be applied.

[0038]

According to the data transmitting apparatus of the present invention, when transmitting data to a plurality of destinations in parallel, it is possible to appropriately distribute the amount of data transmitted to each destination.
Therefore, it is possible to suppress the accumulation of frames in the buffer in the middle of the path and the occurrence of play in the data transfer capability of the path.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram illustrating a configuration and an operation of a storage subsystem according to a first embodiment.

FIG. 2 is a transfer rate table according to the first embodiment;
It is a conceptual diagram of an intermediate buffer and a data transfer request flag.

FIG. 3 is a flowchart illustrating a data transfer control procedure of the transmission buffer controller according to the first embodiment;

FIG. 4 is a flowchart illustrating a process of calculating an assigned amount of a data transfer buffer according to a second embodiment;

[Explanation of symbols]

100: storage control device, 101 to 103: central processing unit, 104: dynamic switch, 105: drive, 106: service processor, 107: remote console, 108: connection port, 109: transmission buffer controller, 110: reception / command controller ,
112: data transfer buffer, 114: intermediate buffer,
116: transfer rate storage table, 117: data transfer request flag, 1011 to 1013: transfer destination connection port,
1021 to 1022: converter, 1030: line

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Misako Tamura 2880 Kozu, Kozuhara-shi, Kanagawa Prefecture Inside the Hitachi, Ltd. Storage Systems Division (72) Inventor Noboru Furumi 2880 Kozu, Kozu-shi, Odawara-shi, Kanagawa Hitachi Storage Corporation F term in the system division (reference) 5B014 EB03 GC06 GC14 GC15 5B077 AA02 AA14 AA15 AA16 AA23

Claims (5)

[Claims] 1. A data transmission means for transmitting data to each of a plurality of destinations by a predetermined data unit in order to each of the plurality of destinations, and a path to each of the plurality of destinations. Transfer rate input means for inputting a data transfer rate of each of the plurality of transmission destinations, and when transmitting data to each of the plurality of transmission destinations, an opportunity to sequentially transmit a predetermined data unit to the plurality of transmission destinations at a time. A data transmission device, comprising: transmission timing control means for controlling according to a transfer rate. 2. A data transmitting means for transmitting data to each of a plurality of destinations by a predetermined data unit in order to each of the plurality of destinations, and a path to each of the plurality of destinations. Data transfer rate calculating means for measuring an average number of I / Os per unit time and an average data length, and obtaining a data transfer rate of each path based on the measurement result, and data for each of the plurality of destinations. Data transmission device, comprising: transmission timing control means for controlling, in accordance with the data transfer rate, a timing of transmitting a predetermined data unit to the plurality of destinations in order when transmitting the data. 3. The data transmission device according to claim 1, wherein the transmission timing control means sets a ratio of a timing of transmitting a predetermined data unit to each transmission destination.
A data transmission device for controlling based on a ratio of a data transfer rate corresponding to each transmission destination. 4. The data transmission device according to claim 3, wherein the transmission timing control means sets a ratio of a timing of transmitting a predetermined data unit to a transmission destination having a low data transfer rate according to the transmission destination. A data transmission rate that is higher than a data transfer rate. 5. A data transmission means for transmitting data to each of a plurality of destinations by a predetermined data unit in order to each of the plurality of destinations, and a priority of each of the plurality of destinations Priority storing means for respectively storing, and when transmitting data to each of the plurality of destinations, an opportunity to sequentially transmit a predetermined data unit to each of the plurality of destinations in accordance with the priority A data transmission device, comprising: a transmission timing control unit for controlling.