Commit 51f10922 authored by Gabriel Somlo's avatar Gabriel Somlo Committed by Stafford Horne

drivers/soc/litex: support 32-bit subregisters, 64-bit CPUs

Upstream LiteX now defaults to using 32-bit CSR subregisters
(see https://github.com/enjoy-digital/litex/commit/a2b71fde).

This patch expands on commit 22447a99 ("drivers/soc/litex: add
LiteX SoC Controller driver"), adding support for handling both 8-
and 32-bit LiteX CSR (MMIO) subregisters, as determined by the
LITEX_SUBREG_SIZE Kconfig option.

NOTE that while LITEX_SUBREG_SIZE could theoretically be a device
tree property, defining it as a compile-time constant allows for
much better optimization of the resulting code. This is further
supported by the low expected usefulness of deploying the same
kernel across LiteX SoCs built with different CSR-Bus data widths.

Finally, the litex_[read|write][8|16|32|64]() accessors are
redefined in terms of litex_[get|set]_reg(), which, after compiler
optimization, will result in code as efficient as hardcoded shifts,
but with the added benefit of automatically matching the appropriate
LITEX_SUBREG_SIZE.

NOTE that litex_[get|set]_reg() nominally operate on 64-bit data,
but that will also be optimized by the compiler in situations where
narrower data is used from a call site.
Signed-off-by: default avatarGabriel Somlo <gsomlo@gmail.com>
Signed-off-by: default avatarStafford Horne <shorne@gmail.com>
parent ffa4ebc4
......@@ -16,4 +16,16 @@ config LITEX_SOC_CONTROLLER
All drivers that use functions from litex.h must depend on
LITEX.
config LITEX_SUBREG_SIZE
int "Size of a LiteX CSR subregister, in bytes"
depends on LITEX
range 1 4
default 4
help
LiteX MMIO registers (referred to as Configuration and Status
registers, or CSRs) are spread across adjacent 8- or 32-bit
subregisters, located at 32-bit aligned MMIO addresses. Use
this to select the appropriate size (1 or 4 bytes) matching
your particular LiteX build.
endmenu
......@@ -58,7 +58,8 @@ static int litex_check_csr_access(void __iomem *reg_addr)
/* restore original value of the SCRATCH register */
litex_write32(reg_addr + SCRATCH_REG_OFF, SCRATCH_REG_VALUE);
pr_info("LiteX SoC Controller driver initialized");
pr_info("LiteX SoC Controller driver initialized: subreg:%d, align:%d",
LITEX_SUBREG_SIZE, LITEX_SUBREG_ALIGN);
return 0;
}
......
......@@ -10,17 +10,14 @@
#define _LINUX_LITEX_H
#include <linux/io.h>
#include <linux/types.h>
#include <linux/compiler_types.h>
/*
* The parameters below are true for LiteX SoCs configured for 8-bit CSR Bus,
* 32-bit aligned.
*
* Supporting other configurations will require extending the logic in this
* header and in the LiteX SoC controller driver.
*/
#define LITEX_SUBREG_SIZE 0x1
/* LiteX SoCs support 8- or 32-bit CSR Bus data width (i.e., subreg. size) */
#if defined(CONFIG_LITEX_SUBREG_SIZE) && \
(CONFIG_LITEX_SUBREG_SIZE == 1 || CONFIG_LITEX_SUBREG_SIZE == 4)
#define LITEX_SUBREG_SIZE CONFIG_LITEX_SUBREG_SIZE
#else
#error LiteX subregister size (LITEX_SUBREG_SIZE) must be 4 or 1!
#endif
#define LITEX_SUBREG_SIZE_BIT (LITEX_SUBREG_SIZE * 8)
/* LiteX subregisters of any width are always aligned on a 4-byte boundary */
......@@ -36,25 +33,32 @@ static inline u32 _read_litex_subregister(void __iomem *addr)
return le32_to_cpu((__le32 __force)readl(addr));
}
#define WRITE_LITEX_SUBREGISTER(val, base_offset, subreg_id) \
_write_litex_subregister(val, (base_offset) + \
LITEX_SUBREG_ALIGN * (subreg_id))
#define READ_LITEX_SUBREGISTER(base_offset, subreg_id) \
_read_litex_subregister((base_offset) + \
LITEX_SUBREG_ALIGN * (subreg_id))
/*
* LiteX SoC Generator, depending on the configuration, can split a single
* logical CSR (Control&Status Register) into a series of consecutive physical
* registers.
*
* For example, in the configuration with 8-bit CSR Bus, 32-bit aligned (the
* default one for 32-bit CPUs) a 32-bit logical CSR will be generated as four
* 32-bit physical registers, each one containing one byte of meaningful data.
* For example, in the configuration with 8-bit CSR Bus, a 32-bit aligned,
* 32-bit wide logical CSR will be laid out as four 32-bit physical
* subregisters, each one containing one byte of meaningful data.
*
* For details see: https://github.com/enjoy-digital/litex/wiki/CSR-Bus
*
*/
/* number of LiteX subregisters needed to store a register of given reg_size */
#define _litex_num_subregs(reg_size) \
(((reg_size) - 1) / LITEX_SUBREG_SIZE + 1)
/*
* since the number of 4-byte aligned subregisters required to store a single
* LiteX CSR (MMIO) register varies with LITEX_SUBREG_SIZE, the offset of the
* next adjacent LiteX CSR register w.r.t. the offset of the current one also
* depends on how many subregisters the latter is spread across
*/
#define _next_reg_off(off, size) \
((off) + _litex_num_subregs(size) * LITEX_SUBREG_ALIGN)
/*
* The purpose of `litex_set_reg`/`litex_get_reg` is to implement the logic
* of writing to/reading from the LiteX CSR in a single place that can be
* then reused by all LiteX drivers.
......@@ -66,22 +70,17 @@ static inline u32 _read_litex_subregister(void __iomem *addr)
* @reg_size: The width of the CSR expressed in the number of bytes
* @val: Value to be written to the CSR
*
* In the currently supported LiteX configuration (8-bit CSR Bus, 32-bit aligned),
* a 32-bit LiteX CSR is generated as 4 consecutive 32-bit physical registers,
* each one containing one byte of meaningful data.
*
* This function splits a single possibly multi-byte write into a series of
* single-byte writes with a proper offset.
* This function splits a single (possibly multi-byte) LiteX CSR write into
* a series of subregister writes with a proper offset.
*/
static inline void litex_set_reg(void __iomem *reg, ulong reg_size, ulong val)
static inline void litex_set_reg(void __iomem *reg, size_t reg_size, u64 val)
{
ulong shifted_data, shift, i;
for (i = 0; i < reg_size; ++i) {
shift = ((reg_size - i - 1) * LITEX_SUBREG_SIZE_BIT);
shifted_data = val >> shift;
u8 shift = _litex_num_subregs(reg_size) * LITEX_SUBREG_SIZE_BIT;
WRITE_LITEX_SUBREGISTER(shifted_data, reg, i);
while (shift > 0) {
shift -= LITEX_SUBREG_SIZE_BIT;
_write_litex_subregister(val >> shift, reg);
reg += LITEX_SUBREG_ALIGN;
}
}
......@@ -92,89 +91,61 @@ static inline void litex_set_reg(void __iomem *reg, ulong reg_size, ulong val)
*
* Return: Value read from the CSR
*
* In the currently supported LiteX configuration (8-bit CSR Bus, 32-bit aligned),
* a 32-bit LiteX CSR is generated as 4 consecutive 32-bit physical registers,
* each one containing one byte of meaningful data.
*
* This function generates a series of single-byte reads with a proper offset
* and joins their results into a single multi-byte value.
* This function generates a series of subregister reads with a proper offset
* and joins their results into a single (possibly multi-byte) LiteX CSR value.
*/
static inline ulong litex_get_reg(void __iomem *reg, ulong reg_size)
static inline u64 litex_get_reg(void __iomem *reg, size_t reg_size)
{
ulong shifted_data, shift, i;
ulong result = 0;
for (i = 0; i < reg_size; ++i) {
shifted_data = READ_LITEX_SUBREGISTER(reg, i);
shift = ((reg_size - i - 1) * LITEX_SUBREG_SIZE_BIT);
result |= (shifted_data << shift);
u64 r;
u8 i;
r = _read_litex_subregister(reg);
for (i = 1; i < _litex_num_subregs(reg_size); i++) {
r <<= LITEX_SUBREG_SIZE_BIT;
reg += LITEX_SUBREG_ALIGN;
r |= _read_litex_subregister(reg);
}
return result;
return r;
}
static inline void litex_write8(void __iomem *reg, u8 val)
{
WRITE_LITEX_SUBREGISTER(val, reg, 0);
litex_set_reg(reg, sizeof(u8), val);
}
static inline void litex_write16(void __iomem *reg, u16 val)
{
WRITE_LITEX_SUBREGISTER(val >> 8, reg, 0);
WRITE_LITEX_SUBREGISTER(val, reg, 1);
litex_set_reg(reg, sizeof(u16), val);
}
static inline void litex_write32(void __iomem *reg, u32 val)
{
WRITE_LITEX_SUBREGISTER(val >> 24, reg, 0);
WRITE_LITEX_SUBREGISTER(val >> 16, reg, 1);
WRITE_LITEX_SUBREGISTER(val >> 8, reg, 2);
WRITE_LITEX_SUBREGISTER(val, reg, 3);
litex_set_reg(reg, sizeof(u32), val);
}
static inline void litex_write64(void __iomem *reg, u64 val)
{
WRITE_LITEX_SUBREGISTER(val >> 56, reg, 0);
WRITE_LITEX_SUBREGISTER(val >> 48, reg, 1);
WRITE_LITEX_SUBREGISTER(val >> 40, reg, 2);
WRITE_LITEX_SUBREGISTER(val >> 32, reg, 3);
WRITE_LITEX_SUBREGISTER(val >> 24, reg, 4);
WRITE_LITEX_SUBREGISTER(val >> 16, reg, 5);
WRITE_LITEX_SUBREGISTER(val >> 8, reg, 6);
WRITE_LITEX_SUBREGISTER(val, reg, 7);
litex_set_reg(reg, sizeof(u64), val);
}
static inline u8 litex_read8(void __iomem *reg)
{
return READ_LITEX_SUBREGISTER(reg, 0);
return litex_get_reg(reg, sizeof(u8));
}
static inline u16 litex_read16(void __iomem *reg)
{
return (READ_LITEX_SUBREGISTER(reg, 0) << 8)
| (READ_LITEX_SUBREGISTER(reg, 1));
return litex_get_reg(reg, sizeof(u16));
}
static inline u32 litex_read32(void __iomem *reg)
{
return (READ_LITEX_SUBREGISTER(reg, 0) << 24)
| (READ_LITEX_SUBREGISTER(reg, 1) << 16)
| (READ_LITEX_SUBREGISTER(reg, 2) << 8)
| (READ_LITEX_SUBREGISTER(reg, 3));
return litex_get_reg(reg, sizeof(u32));
}
static inline u64 litex_read64(void __iomem *reg)
{
return ((u64)READ_LITEX_SUBREGISTER(reg, 0) << 56)
| ((u64)READ_LITEX_SUBREGISTER(reg, 1) << 48)
| ((u64)READ_LITEX_SUBREGISTER(reg, 2) << 40)
| ((u64)READ_LITEX_SUBREGISTER(reg, 3) << 32)
| ((u64)READ_LITEX_SUBREGISTER(reg, 4) << 24)
| ((u64)READ_LITEX_SUBREGISTER(reg, 5) << 16)
| ((u64)READ_LITEX_SUBREGISTER(reg, 6) << 8)
| ((u64)READ_LITEX_SUBREGISTER(reg, 7));
return litex_get_reg(reg, sizeof(u64));
}
#endif /* _LINUX_LITEX_H */
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