SH7263 Datasheet, PDF(323/1862 Page) Renesas Technology Corp – Renesas 32-Bit RISC Microcomputer SuperHTM RISC engine Family / SH7260 Series

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SH7263 Datasheet, PDF (323/1862 Pages) Renesas Technology Corp – Renesas 32-Bit RISC Microcomputer SuperHTM RISC engine Family / SH7260 Series

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Section 9 Bus State Controller (BSC)

9.5 Operation

9.5.1 Endian/Access Size and Data Alignment

This LSI supports both big endian, in which the most significant byte (MSB) of data is that in the

direction of the 0th address, and little endian, in which the least significant byte (LSB) is that in

the direction of the 0th address. In the initial state after a power-on reset, all areas will be in big

endian mode. Little endian cannot be selected for area 0. However, the endian of areas 1 to 7 can

be changed by the setting in the CSnBCR register setting as long as the target space is not being

accessed.

Three data bus widths (8 bits, 16 bits, and 32 bits) are selectable for areas 1 to 7, allowing the

connection of normal memory and of SRAM with byte selection. Two data bus widths (16 bits and

32 bits) are available for SDRAM. Two data bus widths (8 bits and 16 bits) are available for the

PCMCIA interface. For MPX-I/O, the data bus width can be fixed to either 8 or 16 bits, or made

selectable as 8 bits or 16 bits by one of the address lines. The data bus width for burst MPX-I/O is

fixed at 32 bits. Data alignment is in accord with the data bus width selected for the device. This

also means that four read operations are required to read longword data from a byte-width device.

In this LSI, data alignment and conversion of data length is performed automatically between the

respective interfaces. The data bus width of area 0 is fixed to 16 bits or 32 bits by the MD pin

setting at a power-on reset.

Tables 9.5 to 9.10 show the relationship between device data width and access unit. Note that the

correspondence between addresses and strobe signals for the 32- and 16-bit bus widths depends on

the endian setting. For example, with big endian and a 32-bit bus width, WE3 corresponds to the

0th address, which is represented by WE0 when little endian has been selected. Area 0 cannot be

set to little endian mode. In addition, fetching instructions from a little endian area can be difficult

because 32-bit and 16-bit accesses are mixed, so big endian mode should be used for instruction

execution.

Rev. 2.00 Mar. 14, 2008 Page 289 of 1824

REJ09B0290-0200

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