> The MTIME register is a 64-bit read-write register

Is the device required to allow only 64-bit accesses to these registers?  Can a device allow 32-bit accesses?  Can a device only support 32-bit accesses?  If only one size or the other, how will SW know (e.g., in DT)?

Lastly, it seems like all this can just be said in the ACLINT spec.  The platform specs will automatically then inherit this as part of using ACLINT (or parts of ACLINT).

Both MTIME and MTIMECMP are 64-bit wide registers from device perspective (i.e. from ACLINT specification perspective). The ACLINT specification does not mandate 32-bit or 64-bit accesses for RISC-V HARTs. This means by default software will assume 64-bit accesses on RV64 and 32-bit accesses on RV32. We can certainly have an optional boolean DT property “mtimer,64bit-access-not-supported” which will force software to use 32-bit accesses on RV64 system.

On Fri, Jul 16, 2021 at 8:43 PM Anup Patel <Anup.Patel@...> wrote:

Both MTIME and MTIMECMP are 64-bit wide registers from device perspective (i.e. from ACLINT specification perspective). The ACLINT specification does not mandate 32-bit or 64-bit accesses for RISC-V

HARTs. This means by default software will assume 64-bit accesses on RV64 and 32-bit accesses on RV32. We can certainly have an optional boolean DT property “mtimer,64bit-access-not-supported” which will force software to use 32-bit accesses on RV64 system.

While these registers are architecturally 64-bit registers, in many systems they will be accessed over a simple 32-bit bus that doesn't support 64-bit accesses.  This will probably be true in many systems (for example some (or maybe most?) SiFive SoCs such as the FU540 SoC).

  Who wants to spend the hardware on a 2x wide bus for negligible benefit.

  Plus some common bus standards won't support both 32-bit and 64-bit accesses, which complicates mapping and accessing 32-bit registers over a bus that only supports 64-bit accesses.  (Use of a 32-bit bus will tend to be true in both embedded and even high-end systems.  In the latter case the main coherent bus may be quite wide and capable of multi-width accesses, but no one wants to impose the complexity of interfacing to that bus onto all the SoC devices that have memory-mapped registers and want to have the simplest possible bus standard to interface to.)

The point of what was suggested as a result of the email discussions with Andrew a year ago, is that support for the common case should be required (e.g. 32-bit accesses) and then have a DT property that says 64-bit accesses may also be used by software.

Greg

  Who wants to spend the hardware on a 2x wide bus for negligible benefit.

While I agree, I view this as an almost orthogonal concern: bus width doesn’t set a limit on access width.

The point of what was suggested as a result of the email discussions with Andrew a year ago, is that support for the common case should be required (e.g. 32-bit accesses) and then have a DT property that says 64-bit accesses may also be used by software.

I have to admit I don’t recall that thread. Can you forward along a pointer?

Common AMBA utility bus standards like the AXI-Lite buses don't support burst accesses - and hence the bus width does set the access width.  These bus standards are intended to be simple and sufficient for accessing memory-mapped registers.

On Fri, Jul 16, 2021 at 10:10 PM Greg Favor <gfavor@...> wrote:

Common AMBA utility bus standards like the AXI-Lite buses don't support burst accesses - and hence the bus width does set the access width.  These bus standards are intended to be simple and sufficient for accessing memory-mapped registers.

Add to the list the popular APB bus standard used by many IPs for access to their memory-mapped registers.  It only supports up to 32-bit accesses.

In essence, is RV64 going to effectively outlaw ready use of common 32-bit "utility" AMBA bus standards in RV64 systems (especially since there will be a growing number of 64-bit memory-mapped registers defined by extensions this year and going forward)?