CN116700445A - Full flash ARM storage server based on distributed storage hardware architecture - Google Patents

Abstract

The invention discloses a full flash ARM storage server based on a distributed storage hardware architecture, which comprises a storage system, a network switching system, a BMC management system and a power supply and heat dissipation system, wherein the storage system is connected with the BMC management system; the storage system consists of 12 storage nodes which are arranged in 4 rows and 3 columns in a 2U chassis, the storage nodes are in pluggable modular design, a storage node controller consists of a low-power-consumption multi-core ARM processor, the storage system is accessed into a network switching system by adopting a ten-thousand-megabyte or twenty-thousand-megabyte network, and data transmission and service communication are carried out in a network switching mode; communication with the BMC management system through a management bus interface; accessing 2 hard disks through 2 SATA bus interfaces to realize the data access function; the invention has the advantages of high hardware reliability, low power consumption and the like.

Description

Full flash ARM storage server based on distributed storage hardware architecture

Technical Field

The invention relates to the technical field of servers, in particular to a full-flash ARM storage server based on a distributed storage hardware architecture.

Background

Along with the continuous development of information technology, the digital transformation and upgrading progress of each industry is accelerated, the total global data amount is increased in an explosive manner, and in the times of big data, cloud computing and Internet of things, the challenges encountered in the aspects of data storage, performance, power consumption, deployment, management and the like are more and more:

1. the rapid growth of data brings about a need for more storage capacity;

2. the data access performance in many data application scenes is higher, and lower delay, higher IO performance and larger bandwidth are required;

3. the large-scale IT infrastructure construction puts higher demands on low hardware cost, requires lower cost per TB storage capacity, and lower maintenance and management costs;

4. the problem of overhigh data energy storage consumption has become a great challenge facing the data center, and the control of energy consumption level and the construction of a green data center become important contents of digital economic development of China.

The reconstruction and upgrading of the IT infrastructure to meet the ever-increasing data demands is a long-felt challenge for manufacturers upstream and downstream of data storage, and continuous technical innovation and breakthrough are required.

Data is calculated and stored separately, and different data has different characteristics: some data require large capacity and some data require higher access performance (low latency, high IOPS, high bandwidth).

In addition, most of mass data generated by each industry is unstructured data, and under the promotion of exponential growth of the unstructured data, the distributed storage has the advantages in aspects of expansibility, performance, multi-protocol support, reliability, concurrency and the like, so that the potential of adapting to application scenes is huge, and the distributed storage is dominant gradually in the storage field.

However, it is difficult to help users achieve optimal data storage by a storage server hardware device, and thus a full flash ARM storage server hardware solution based on a distributed storage hardware architecture is needed.

Disclosure of Invention

The invention provides a full flash ARM storage server based on a distributed storage hardware architecture, which can effectively solve the technical problems.

In order to achieve the above purpose, the present invention provides the following technical solutions: a full flash ARM storage server based on a distributed storage hardware architecture comprises a storage system, a network switching system, a BMC management system and a power supply and heat dissipation system;

the storage system consists of 12 storage nodes which are arranged in 4 rows and 3 columns in a 2U chassis, the storage nodes are in pluggable modular design, a storage node controller consists of a low-power-consumption multi-core ARM processor, the storage system is accessed into a network switching system by adopting a ten-thousand-megabyte or twenty-thousand-megabyte network, and data transmission and service communication are carried out in a network switching mode; communication with the BMC management system through a management bus interface; accessing 2 hard disks through 2 SATA bus interfaces to realize the data access function; the storage node main board is connected into a 2U server backboard through an onboard node connector, and each storage node controls 2 hard disks: the disk position 1 and the disk position 2, wherein the disk position 1 is directly expanded by a SATA connector carried by a main board, the disk position 2 is expanded by a SATA adapter plate and a SATA expansion plate, and the disk position structure of the hard disk is designed to be compatible with two physical size hard disk specifications of a 3.5 inch mechanical hard disk and a 2.5 inch mechanical hard disk/SSD solid state hard disk;

the network switching system consists of a network switching board carrying high-performance tera-meganetwork switching chips, the switching chips need to support at least 240Gb of switching capacity, the bandwidth of a lower network is 120Gb, the bandwidth of an upper network is 120Gb, and the ports of the upper network can adopt 5 25Gb SFP28 optical ports;

the BMC management system is based on BMC management board hardware, operates independently of a server service system and is used for implementing server remote control management and hardware state monitoring functions; the BMC management system bus comprises UART, I2C, ethernet and low-speed IO control signals, and realizes the functions of collecting state information and controlling management on the storage node, the network exchange board, the power module and the fan module.

Preferably, the power supply and heat dissipation system consists of a server 1+1 redundant power supply module and a fan module, and the functions of centralized power supply and active heat dissipation of the server hardware system are respectively realized.

Preferably, the BMC management board, the network exchange board, the power module and the fan module all adopt pluggable modular structures.

Compared with the prior art, the invention has the beneficial effects that:

1. high storage density and high application agility: 24 hard disks can be supported in the 2U case, and simultaneously 2.5 inch SATA SSD solid state disks and 3.5 inch SATA mechanical hard disks are compatible. The network architecture design of the distributed storage in the case is matched, the high-capacity mechanical hard disk and the high-performance SSD solid state disk can be mixed and deployed in any proportion in the case, and the layered storage of the cold and hot data is realized in the single case.

2. The inside of the case realizes a high-bandwidth distributed storage micro cluster: the high-speed data exchange transmission is carried out on 12 storage nodes in the case through the tera-mega network and the high-performance network exchange board, each storage node is in loose coupling connection through the network, the high-bandwidth distributed storage micro-cluster is realized in the case, and the distributed storage micro-cluster has the general advantage of distributed storage: high reliability, high expansibility, high performance and strong data straightness.

3. High hardware reliability: the redundant backup of the network switching transmission system is realized through the double-megacard bonding technology of the storage node and the double-exchange board hardware design, and the multi-copy backup mechanism of the distributed storage system can effectively avoid hardware single-point faults, so that the reliability of the whole server is greatly improved.

4. Low power consumption: because the storage node controllers are all realized by adopting the low-power ARM processor, the equipment energy consumption can be effectively reduced in the scene of deploying the SSD solid state disk, and the environment-friendly energy conservation and low carbon and environment friendliness of the data center are realized.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a hardware system of a full flash ARM storage server based on a distributed storage hardware architecture;

FIG. 2 is a schematic diagram of a hardware architecture of a storage node of a full flash ARM storage server based on a distributed storage hardware architecture according to the present invention;

FIG. 3 is a network topology diagram of a full flash ARM storage server based on a distributed storage hardware architecture according to the present invention;

FIG. 4 is another network topology diagram of a full flash ARM storage server based on a distributed storage hardware architecture according to the present invention;

fig. 5 is a rear view of a full flash ARM storage server based on a distributed storage hardware architecture according to the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It is also to be understood that the terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be further understood that the term "and/or" as used in the present specification and the appended claims refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.

Noun interpretation:

IOPS: number of read/write operations per second of Input/Output Operations Per Second

SATA: serial Advanced Technology Attachment serial advanced technology attachment, an industry standard based serial hardware driver interface

PCIe: peripheral component interconnect express high-speed serial computer expansion bus

SSD Solid State Disk or Solid State Drive Solid State Disk/Solid State drive

ARM: advanced RISC Machine is a RISC microprocessor with low power consumption and low cost.

Referring to fig. 1, the hardware system of the ARM storage server according to the present invention adopts a modular design, and the whole machine is composed of a structural chassis, a storage node, a back plate, a network switch board, a BMC management board, a fan module and a power module. The system architecture is logically divided into four parts from the business process: the system comprises a storage system, a network switching system, a BMC management system and a power supply and heat dissipation system. The four systems work cooperatively and are combined into a complete storage server complete machine system, and the BMC management system carries out unified operation and management on the server.

The invention provides a full flash ARM storage server based on a distributed storage hardware architecture, which comprises a storage system, a network switching system, a BMC management system and a power supply and heat dissipation system, wherein the storage system is connected with the BMC management system;

1. storage system

The storage system is physically realized by 12 storage nodes, which are distributed in 4 rows and 3 columns in a 2U chassis, and the storage nodes adopt pluggable modular design. The front view of the server is shown in the following figures:

node 1	Node 4	Node 7	Node 10
				Node 2	Node 5	Node 8	Node 11
Node 3	Node 6	Node 9	Node 12

The storage node controller is realized by a low-power-consumption multi-core (4 cores or 8 cores, and more cores are possible in the future) ARM processor, and the ARM processor can select a 4-core or 8-core processor of Marvell and other companies for integrating the tera network card and the SATA controller; the 8-core ARM processor of the PCIe and SATA controllers integrated by the Rayleigh core micro-and other companies can be selected, and the tera-network can be adapted to the tera-network card chip expansion through the PCIe bus.

The storage system is accessed into the network switching system by adopting a tera or a bi-tera network (the bi-tera network can realize redundant backup of the network switching system through a bonding technology), and performs data transmission and service communication in a network switching mode; communication with the BMC management system through a management bus interface (UART, I2C, control IO signals, etc.); 2 hard disks are accessed through 2 SATA bus interfaces, so that the data access function is realized. The storage node main board is connected to the 2U server backboard through an onboard node connector, and each storage node can control 2 hard disks: the disk bit 1 is directly expanded by the SATA connector on the motherboard, and the disk bit 2 is expanded by the SATA adapter board (or adapter line) and the SATA expansion board. The hard disk position structure is compatible with two physical size hard disk specifications of a 3.5 inch mechanical hard disk and a 2.5 inch mechanical hard disk/SSD solid state hard disk. The hardware architecture of the storage node is shown in fig. 2.

2. Network switching system

The network switching system is realized by network switching boards carrying high-performance tera-network switching chips, and each network switching board is equivalent to a built-in high-performance tera-network switch. The switching chip needs to support at least 240Gb of switching capacity, namely, the bandwidth of a downlink (carrying out data switching transmission with 12 storage nodes) network is 120Gb (12 x 10 Gb), and the bandwidth of an uplink (carrying out data switching transmission with an external service network) network is 120Gb as well, so that the non-blocking forwarding of data can be realized in the most extreme application scenario. Considering the realizability of the product, the upper network port can be realized by adopting 5 25Gb SFP28 optical ports through a port link aggregation function.

If the redundancy backup function of the exchange boards is needed to be realized, 2 exchange boards can be adopted, and 12 10Gb lower network ports of each exchange board are respectively connected with 1 10G network ports of 12 storage node mainboards; the 2 10Gb network ports of the storage node main board adopt Bonding technology to make redundancy of a network port hardware layer, single point failure of single network port application can be prevented, an actual product application scene can be configured into a Bond mode 1 (namely a main standby mode), only a main network card works in the mode, a backup network card does not work, and only when a main network interface fails (such as a switching board corresponding to the interface fails), the system starts the backup network card to work according to configuration, so that equipment can still serve outside, and a failure protection function is achieved. The network topology of data exchange transmission between the network exchange board and the storage node is shown in fig. 3, wherein the 2U back board only plays a role of a physical carrier for signal interconnection for network signals, and does not participate in any signal conversion.

Through the two-layer Ethernet switching function of the network switching system, not only can the high-speed data switching transmission between the storage nodes be realized, but also the high-speed data switching transmission between the storage nodes and an external service network can be realized, and the purposes of high-speed data access and backup restoration are achieved by matching with the high-speed IO performance of the SSD.

If the network performance needs to be further improved, the 2 network switch boards can be logically combined into one network switch board through a switch stacking technology. Through the stacking technology, high reliability of the network and large data volume forwarding of the network can be realized, and meanwhile, network management of the switching board is simplified. Meanwhile, the network bandwidth of each storage node can be doubled (namely, 20Gb is reached) by matching with the double-megamega network card bonding technology of the storage node; likewise, the upper network bandwidth of 2 physical switch boards (already combined into one logical switch board by stacking technology) is doubled by the link aggregation function. The network topology for data exchange transmission between a network switch board and storage nodes using stacking techniques is shown in fig. 4.

3. BMC management system and power supply and heat dissipation system

The BMC management system is based on BMC management board hardware, the running of the BMC management system is independent of a server service system, and the BMC management system can run by itself only by plugging a power line into a server, and is used for implementing functions such as server remote control management, hardware state monitoring and the like. The BMC management system bus comprises UART, I2C, ethernet, low-speed IO control signals and the like, and achieves the functions of collecting state information and controlling and managing the storage nodes, the network exchange board, the power module and the fan module.

The power supply and heat dissipation system consists of a server 1+1 redundant power supply module and a fan module, and the functions of centralized power supply and active heat dissipation of the server hardware system are respectively realized, so that the whole hardware system is always in a healthy working environment.

The BMC management system and the power and heat dissipation system are not core technologies of this patent and will not be described in detail herein.

Referring to fig. 5, a rear view of the server is shown, and the BMC management board, the network switch board, the power module, and the fan module are all configured in a pluggable modular design.

The invention adopts a single storage server hardware device to realize the following steps:

the 1.2U storage server device supports 24 2.5 inch SSD solid state disks, and high-speed data access performance is achieved by using a full flash memory technology.

2. The device supports 24 mechanical hard disk HDDs of 3.5 inches at the same time, and can meet the application scene of high-capacity and high-density warm data or cold data access.

3.24 hard disk positions, the quantity proportion of SSD solid state hard disk and mechanical hard disk HDD can be flexibly deployed, the layered storage of cold and hot data can be realized in a single machine case, and the balance between performance and cost is achieved.

4. The device supports 12 storage controller nodes (each node supports 2 hard disks), the 12 storage nodes exchange and transmit data through a high-performance tera Ethernet exchange board arranged in a case, and a small distributed storage micro-cluster can be formed by networking in a single server case; multiple storage servers can form a larger-scale distributed storage cluster through external networking.

The storage controllers of the 5.12 storage nodes are all realized by adopting low-power-consumption 4-core or 8-core ARM processors, so that the functions of equipment can be effectively reduced, and the balance between the performance and the power consumption is achieved.

Compared with the prior art, the invention has the beneficial effects that:

1. high storage density and high application agility: 24 hard disks can be supported in the 2U case, and simultaneously 2.5 inch SATA SSD solid state disks and 3.5 inch SATA mechanical hard disks are compatible. The network architecture design of the distributed storage in the case is matched, the high-capacity mechanical hard disk and the high-performance SSD solid state disk can be mixed and deployed in any proportion in the case, and the layered storage of the cold and hot data is realized in the single case.

2. The inside of the case realizes a high-bandwidth distributed storage micro cluster: the high-speed data exchange transmission is carried out on 12 storage nodes in the case through the tera-mega network and the high-performance network exchange board, each storage node is in loose coupling connection through the network, the high-bandwidth distributed storage micro-cluster is realized in the case, and the distributed storage micro-cluster has the general advantage of distributed storage: high reliability, high expansibility, high performance and strong data straightness.

3. High hardware reliability: the redundant backup of the network switching transmission system is realized through the double-megacard bonding technology of the storage node and the double-exchange board hardware design, and the multi-copy backup mechanism of the distributed storage system can effectively avoid hardware single-point faults, so that the reliability of the whole server is greatly improved.

4. Low power consumption: because the storage node controllers are all realized by adopting the low-power ARM processor, the equipment energy consumption can be effectively reduced in the scene of deploying the SSD solid state disk, and the environment-friendly energy conservation and low carbon and environment friendliness of the data center are realized.

While the invention has been described with reference to certain preferred embodiments, it will be understood by those skilled in the art that various changes and substitutions of equivalents may be made and equivalents will be apparent to those skilled in the art without departing from the scope of the invention. Therefore, the protection scope of the invention is subject to the protection scope of the claims.

Claims (3)

1. The full flash ARM storage server based on the distributed storage hardware architecture is characterized by comprising a storage system, a network switching system, a BMC management system and a power supply and heat dissipation system;

the storage system consists of 12 storage nodes which are arranged in 4 rows and 3 columns in a 2U chassis, the storage nodes are in pluggable modular design, a storage node controller consists of a low-power-consumption multi-core ARM processor, the storage system is accessed into a network switching system by adopting a ten-thousand-megabyte or twenty-thousand-megabyte network, and data transmission and service communication are carried out in a network switching mode; communication with the BMC management system through a management bus interface; accessing 2 hard disks through 2 SATA bus interfaces to realize the data access function; the storage node main board is connected into a 2U server backboard through an onboard node connector, and each storage node controls 2 hard disks: the disk position 1 and the disk position 2, wherein the disk position 1 is directly expanded by a SATA connector carried by a main board, the disk position 2 is expanded by a SATA adapter plate and a SATA expansion plate, and the disk position structure of the hard disk is designed to be compatible with two physical size hard disk specifications of a 3.5 inch mechanical hard disk and a 2.5 inch mechanical hard disk/SSD solid state hard disk;

the network switching system consists of a network switching board carrying high-performance tera-meganetwork switching chips, the switching chips need to support at least 240Gb of switching capacity, the bandwidth of a lower network is 120Gb, the bandwidth of an upper network is 120Gb, and the ports of the upper network can adopt 5 25Gb SFP28 optical ports;

the BMC management system is based on BMC management board hardware, operates independently of a server service system and is used for implementing server remote control management and hardware state monitoring functions; the BMC management system bus comprises UART, I2C, ethernet and low-speed IO control signals, and realizes the functions of collecting state information and controlling management on the storage node, the network exchange board, the power module and the fan module.

2. The full flash ARM storage server based on the distributed storage hardware architecture of claim 1, wherein: the power supply and heat dissipation system consists of a server 1+1 redundant power supply module and a fan module, and the functions of centralized power supply and active heat dissipation of a server hardware system are respectively realized.

3. The full flash ARM storage server based on the distributed storage hardware architecture of claim 2, wherein: the BMC management board, the network exchange board, the power module and the fan module all adopt pluggable modular structures.