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SOC Consortium Course Material On Chip Bus National Taiwan University Adopted from National Taiwan University SOC Course Material.

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Presentation on theme: "SOC Consortium Course Material On Chip Bus National Taiwan University Adopted from National Taiwan University SOC Course Material."— Presentation transcript:

1 SOC Consortium Course Material On Chip Bus National Taiwan University Adopted from National Taiwan University SOC Course Material

2 SOC Consortium Course Material 2 Outline  AMBA Bus –Advanced System Bus (ASB) –Advanced High-performance Bus (AHB) –Advanced Peripheral Bus (APB)

3 SOC Consortium Course Material 3 Bus Architecture

4 SOC Consortium Course Material 4 Outline  AMBA Bus –Advanced System Bus High performance Pipelined operation Multiple bus master –Advanced High-performance Bus –Advanced Peripheral Bus

5 SOC Consortium Course Material 5 Outline  AMBA Bus –Advanced System Bus –Advanced High-performance Bus High performance Pipelined operation Multiple bus master Burst transfers  Advanced Peripheral Bus

6 SOC Consortium Course Material 6 AHB simple Arch.

7 SOC Consortium Course Material 7 AHB Components  AHB Components –AHB master is able to initiate read and write operations by providing an address and control information. Only one bus master is allowed to actively use the bus at any one time.(max. 16) –AHB slave responds to a read or write operation within a given address-space range. The bus slave signals back to the active master the success, failure or waiting of the data transfer.

8 SOC Consortium Course Material 8 AHB Components(ii)  AHB Components –AHB arbiter ensures that only one bus master at a time is allowed to initiate data transfers. –AHB decoder is used to decode the address of each transfer and provide a select signal for the slave that is involved in the transfer. A single centralized decoder is required in all AHB implementations.

9 SOC Consortium Course Material 9 AHB Signals(i)  AHB Signals can be classified as –Clock (HCLK) –Address and read/write data (HADDR, HRDATA, HWDATA) –Arbitration (HGRANTx, HMASTER, HMASTLOCK,…) –Control signal (HRESETn,…) –Response signal(HREADY, HRESP)

10 SOC Consortium Course Material 10 AHB Signals(ii)  Transfer signals –HCLK bus clock. All signal timings are related to the rising edge. –HADDR[31:0] 32 bits system bus –HWDATA/HRDATA [31:0] 32 bits write/read data bus –HWRITE High: write data Low: read data –HREADY Transfer done

11 SOC Consortium Course Material 11 AHB Signals(ii) Basic Transfer  Each transfer consists of –An address and control cycle –One or more cycles for the data

12 SOC Consortium Course Material 12 AHB Arch.

13 SOC Consortium Course Material 13 AHB Signals(iii)  Control signals –HTRANS[1:0] Current transfer type –HBURST[2:0] When sequential transfer, control transfer relation –HSIZE[2:0] Control transfer size=2^HSIZE bytes(max=1024bits)

14 SOC Consortium Course Material 14 AHB Signals(iii)-HTRANS  HTRANS[1:0] –IDLE: master don’t need data to be transfer. –BUSY: This transfer type indicates that the bus master is continuing with a burst of transfers. –NONSEQ: The address and control signals are unrelated to the previous transfer. –SEQ: the address is related to the previous transfer.

15 SOC Consortium Course Material 15 Burst Operation  AMBA AHB burst operation – 4-beat, 8-beat, 16-beat, single transfer, and undefined-length transfer. – Both incrementing and wrapping bursts are supported.  Incrementing burst – Incrementing bursts access sequential locations and the address of each transfer in the burst is just an increment of the previous address.  Wrapping burst – For wrapping bursts, if the start address of the transfer is not aligned to the total number of bytes in the burst (size x beats), then the address of the transfer in the burst will wrap when the boundary is reached.

16 SOC Consortium Course Material 16 AHB Signals (iii)-HBURST

17 SOC Consortium Course Material 17 AHB Signals(iii)-HBURST

18 SOC Consortium Course Material 18 AHB Signals(iv)  Response signals –HREADY Transfer done, ready for next transfer –HRESP[1:0] OKAY transfer complete ERROR transfer failure(ex: write ROM) RETRY higher priority master can access bus SPLIT other master can access bus

19 SOC Consortium Course Material 19 AHB Signals(v)  Arbiter signals –HGRANTx Select active bus master –HMASTER[3:0] Indicate which bus master is currently performing a transfer

20 SOC Consortium Course Material 20 Master signal

21 SOC Consortium Course Material 21 Arbiter signal

22 SOC Consortium Course Material 22 Slave signal

23 SOC Consortium Course Material 23 Outline  AMBA Bus –Advanced System Bus –Advanced High-performance Bus –Advanced Peripheral Bus Low power Latched address and control Simple interface Suitable for many peripherals

24 SOC Consortium Course Material 24 APB state diagram

25 SOC Consortium Course Material 25 APB signals  APB character –Always two cycle transfer –No wait cycle and response signal  APB signals –PCLK Bus clock , rising edge is used to time all transfers. –PRESETn APB reset 。 active Low.

26 SOC Consortium Course Material 26 APB signals  PADDR[31:0] APB address bus.  PSELx Indicates that the slave device is selected. There is a PSELx signal for each slave.  PENABLE Indicates the second cycle of an APB transfer.  PWRITE Transfer direction. High for write access, Low for read access.  PRDATA Read data bus  PWDATA Write data bus

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