klipper/lib/rp2040/hardware/regs/sio.h

1657 lines
84 KiB
C

/**
* Copyright (c) 2021 Raspberry Pi (Trading) Ltd.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
// =============================================================================
// Register block : SIO
// Version : 1
// Bus type : apb
// Description : Single-cycle IO block
// Provides core-local and inter-core hardware for the two
// processors, with single-cycle access.
// =============================================================================
#ifndef HARDWARE_REGS_SIO_DEFINED
#define HARDWARE_REGS_SIO_DEFINED
// =============================================================================
// Register : SIO_CPUID
// Description : Processor core identifier
// Value is 0 when read from processor core 0, and 1 when read
// from processor core 1.
#define SIO_CPUID_OFFSET _u(0x00000000)
#define SIO_CPUID_BITS _u(0xffffffff)
#define SIO_CPUID_RESET "-"
#define SIO_CPUID_MSB _u(31)
#define SIO_CPUID_LSB _u(0)
#define SIO_CPUID_ACCESS "RO"
// =============================================================================
// Register : SIO_GPIO_IN
// Description : Input value for GPIO pins
// Input value for GPIO0...29
#define SIO_GPIO_IN_OFFSET _u(0x00000004)
#define SIO_GPIO_IN_BITS _u(0x3fffffff)
#define SIO_GPIO_IN_RESET _u(0x00000000)
#define SIO_GPIO_IN_MSB _u(29)
#define SIO_GPIO_IN_LSB _u(0)
#define SIO_GPIO_IN_ACCESS "RO"
// =============================================================================
// Register : SIO_GPIO_HI_IN
// Description : Input value for QSPI pins
// Input value on QSPI IO in order 0..5: SCLK, SSn, SD0, SD1, SD2,
// SD3
#define SIO_GPIO_HI_IN_OFFSET _u(0x00000008)
#define SIO_GPIO_HI_IN_BITS _u(0x0000003f)
#define SIO_GPIO_HI_IN_RESET _u(0x00000000)
#define SIO_GPIO_HI_IN_MSB _u(5)
#define SIO_GPIO_HI_IN_LSB _u(0)
#define SIO_GPIO_HI_IN_ACCESS "RO"
// =============================================================================
// Register : SIO_GPIO_OUT
// Description : GPIO output value
// Set output level (1/0 -> high/low) for GPIO0...29.
// Reading back gives the last value written, NOT the input value
// from the pins.
// If core 0 and core 1 both write to GPIO_OUT simultaneously (or
// to a SET/CLR/XOR alias),
// the result is as though the write from core 0 took place first,
// and the write from core 1 was then applied to that intermediate
// result.
#define SIO_GPIO_OUT_OFFSET _u(0x00000010)
#define SIO_GPIO_OUT_BITS _u(0x3fffffff)
#define SIO_GPIO_OUT_RESET _u(0x00000000)
#define SIO_GPIO_OUT_MSB _u(29)
#define SIO_GPIO_OUT_LSB _u(0)
#define SIO_GPIO_OUT_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OUT_SET
// Description : GPIO output value set
// Perform an atomic bit-set on GPIO_OUT, i.e. `GPIO_OUT |= wdata`
#define SIO_GPIO_OUT_SET_OFFSET _u(0x00000014)
#define SIO_GPIO_OUT_SET_BITS _u(0x3fffffff)
#define SIO_GPIO_OUT_SET_RESET _u(0x00000000)
#define SIO_GPIO_OUT_SET_MSB _u(29)
#define SIO_GPIO_OUT_SET_LSB _u(0)
#define SIO_GPIO_OUT_SET_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OUT_CLR
// Description : GPIO output value clear
// Perform an atomic bit-clear on GPIO_OUT, i.e. `GPIO_OUT &=
// ~wdata`
#define SIO_GPIO_OUT_CLR_OFFSET _u(0x00000018)
#define SIO_GPIO_OUT_CLR_BITS _u(0x3fffffff)
#define SIO_GPIO_OUT_CLR_RESET _u(0x00000000)
#define SIO_GPIO_OUT_CLR_MSB _u(29)
#define SIO_GPIO_OUT_CLR_LSB _u(0)
#define SIO_GPIO_OUT_CLR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OUT_XOR
// Description : GPIO output value XOR
// Perform an atomic bitwise XOR on GPIO_OUT, i.e. `GPIO_OUT ^=
// wdata`
#define SIO_GPIO_OUT_XOR_OFFSET _u(0x0000001c)
#define SIO_GPIO_OUT_XOR_BITS _u(0x3fffffff)
#define SIO_GPIO_OUT_XOR_RESET _u(0x00000000)
#define SIO_GPIO_OUT_XOR_MSB _u(29)
#define SIO_GPIO_OUT_XOR_LSB _u(0)
#define SIO_GPIO_OUT_XOR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OE
// Description : GPIO output enable
// Set output enable (1/0 -> output/input) for GPIO0...29.
// Reading back gives the last value written.
// If core 0 and core 1 both write to GPIO_OE simultaneously (or
// to a SET/CLR/XOR alias),
// the result is as though the write from core 0 took place first,
// and the write from core 1 was then applied to that intermediate
// result.
#define SIO_GPIO_OE_OFFSET _u(0x00000020)
#define SIO_GPIO_OE_BITS _u(0x3fffffff)
#define SIO_GPIO_OE_RESET _u(0x00000000)
#define SIO_GPIO_OE_MSB _u(29)
#define SIO_GPIO_OE_LSB _u(0)
#define SIO_GPIO_OE_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OE_SET
// Description : GPIO output enable set
// Perform an atomic bit-set on GPIO_OE, i.e. `GPIO_OE |= wdata`
#define SIO_GPIO_OE_SET_OFFSET _u(0x00000024)
#define SIO_GPIO_OE_SET_BITS _u(0x3fffffff)
#define SIO_GPIO_OE_SET_RESET _u(0x00000000)
#define SIO_GPIO_OE_SET_MSB _u(29)
#define SIO_GPIO_OE_SET_LSB _u(0)
#define SIO_GPIO_OE_SET_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OE_CLR
// Description : GPIO output enable clear
// Perform an atomic bit-clear on GPIO_OE, i.e. `GPIO_OE &=
// ~wdata`
#define SIO_GPIO_OE_CLR_OFFSET _u(0x00000028)
#define SIO_GPIO_OE_CLR_BITS _u(0x3fffffff)
#define SIO_GPIO_OE_CLR_RESET _u(0x00000000)
#define SIO_GPIO_OE_CLR_MSB _u(29)
#define SIO_GPIO_OE_CLR_LSB _u(0)
#define SIO_GPIO_OE_CLR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_OE_XOR
// Description : GPIO output enable XOR
// Perform an atomic bitwise XOR on GPIO_OE, i.e. `GPIO_OE ^=
// wdata`
#define SIO_GPIO_OE_XOR_OFFSET _u(0x0000002c)
#define SIO_GPIO_OE_XOR_BITS _u(0x3fffffff)
#define SIO_GPIO_OE_XOR_RESET _u(0x00000000)
#define SIO_GPIO_OE_XOR_MSB _u(29)
#define SIO_GPIO_OE_XOR_LSB _u(0)
#define SIO_GPIO_OE_XOR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OUT
// Description : QSPI output value
// Set output level (1/0 -> high/low) for QSPI IO0...5.
// Reading back gives the last value written, NOT the input value
// from the pins.
// If core 0 and core 1 both write to GPIO_HI_OUT simultaneously
// (or to a SET/CLR/XOR alias),
// the result is as though the write from core 0 took place first,
// and the write from core 1 was then applied to that intermediate
// result.
#define SIO_GPIO_HI_OUT_OFFSET _u(0x00000030)
#define SIO_GPIO_HI_OUT_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OUT_RESET _u(0x00000000)
#define SIO_GPIO_HI_OUT_MSB _u(5)
#define SIO_GPIO_HI_OUT_LSB _u(0)
#define SIO_GPIO_HI_OUT_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OUT_SET
// Description : QSPI output value set
// Perform an atomic bit-set on GPIO_HI_OUT, i.e. `GPIO_HI_OUT |=
// wdata`
#define SIO_GPIO_HI_OUT_SET_OFFSET _u(0x00000034)
#define SIO_GPIO_HI_OUT_SET_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OUT_SET_RESET _u(0x00000000)
#define SIO_GPIO_HI_OUT_SET_MSB _u(5)
#define SIO_GPIO_HI_OUT_SET_LSB _u(0)
#define SIO_GPIO_HI_OUT_SET_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OUT_CLR
// Description : QSPI output value clear
// Perform an atomic bit-clear on GPIO_HI_OUT, i.e. `GPIO_HI_OUT
// &= ~wdata`
#define SIO_GPIO_HI_OUT_CLR_OFFSET _u(0x00000038)
#define SIO_GPIO_HI_OUT_CLR_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OUT_CLR_RESET _u(0x00000000)
#define SIO_GPIO_HI_OUT_CLR_MSB _u(5)
#define SIO_GPIO_HI_OUT_CLR_LSB _u(0)
#define SIO_GPIO_HI_OUT_CLR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OUT_XOR
// Description : QSPI output value XOR
// Perform an atomic bitwise XOR on GPIO_HI_OUT, i.e. `GPIO_HI_OUT
// ^= wdata`
#define SIO_GPIO_HI_OUT_XOR_OFFSET _u(0x0000003c)
#define SIO_GPIO_HI_OUT_XOR_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OUT_XOR_RESET _u(0x00000000)
#define SIO_GPIO_HI_OUT_XOR_MSB _u(5)
#define SIO_GPIO_HI_OUT_XOR_LSB _u(0)
#define SIO_GPIO_HI_OUT_XOR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OE
// Description : QSPI output enable
// Set output enable (1/0 -> output/input) for QSPI IO0...5.
// Reading back gives the last value written.
// If core 0 and core 1 both write to GPIO_HI_OE simultaneously
// (or to a SET/CLR/XOR alias),
// the result is as though the write from core 0 took place first,
// and the write from core 1 was then applied to that intermediate
// result.
#define SIO_GPIO_HI_OE_OFFSET _u(0x00000040)
#define SIO_GPIO_HI_OE_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OE_RESET _u(0x00000000)
#define SIO_GPIO_HI_OE_MSB _u(5)
#define SIO_GPIO_HI_OE_LSB _u(0)
#define SIO_GPIO_HI_OE_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OE_SET
// Description : QSPI output enable set
// Perform an atomic bit-set on GPIO_HI_OE, i.e. `GPIO_HI_OE |=
// wdata`
#define SIO_GPIO_HI_OE_SET_OFFSET _u(0x00000044)
#define SIO_GPIO_HI_OE_SET_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OE_SET_RESET _u(0x00000000)
#define SIO_GPIO_HI_OE_SET_MSB _u(5)
#define SIO_GPIO_HI_OE_SET_LSB _u(0)
#define SIO_GPIO_HI_OE_SET_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OE_CLR
// Description : QSPI output enable clear
// Perform an atomic bit-clear on GPIO_HI_OE, i.e. `GPIO_HI_OE &=
// ~wdata`
#define SIO_GPIO_HI_OE_CLR_OFFSET _u(0x00000048)
#define SIO_GPIO_HI_OE_CLR_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OE_CLR_RESET _u(0x00000000)
#define SIO_GPIO_HI_OE_CLR_MSB _u(5)
#define SIO_GPIO_HI_OE_CLR_LSB _u(0)
#define SIO_GPIO_HI_OE_CLR_ACCESS "RW"
// =============================================================================
// Register : SIO_GPIO_HI_OE_XOR
// Description : QSPI output enable XOR
// Perform an atomic bitwise XOR on GPIO_HI_OE, i.e. `GPIO_HI_OE
// ^= wdata`
#define SIO_GPIO_HI_OE_XOR_OFFSET _u(0x0000004c)
#define SIO_GPIO_HI_OE_XOR_BITS _u(0x0000003f)
#define SIO_GPIO_HI_OE_XOR_RESET _u(0x00000000)
#define SIO_GPIO_HI_OE_XOR_MSB _u(5)
#define SIO_GPIO_HI_OE_XOR_LSB _u(0)
#define SIO_GPIO_HI_OE_XOR_ACCESS "RW"
// =============================================================================
// Register : SIO_FIFO_ST
// Description : Status register for inter-core FIFOs (mailboxes).
// There is one FIFO in the core 0 -> core 1 direction, and one
// core 1 -> core 0. Both are 32 bits wide and 8 words deep.
// Core 0 can see the read side of the 1->0 FIFO (RX), and the
// write side of 0->1 FIFO (TX).
// Core 1 can see the read side of the 0->1 FIFO (RX), and the
// write side of 1->0 FIFO (TX).
// The SIO IRQ for each core is the logical OR of the VLD, WOF and
// ROE fields of its FIFO_ST register.
#define SIO_FIFO_ST_OFFSET _u(0x00000050)
#define SIO_FIFO_ST_BITS _u(0x0000000f)
#define SIO_FIFO_ST_RESET _u(0x00000002)
// -----------------------------------------------------------------------------
// Field : SIO_FIFO_ST_ROE
// Description : Sticky flag indicating the RX FIFO was read when empty. This
// read was ignored by the FIFO.
#define SIO_FIFO_ST_ROE_RESET _u(0x0)
#define SIO_FIFO_ST_ROE_BITS _u(0x00000008)
#define SIO_FIFO_ST_ROE_MSB _u(3)
#define SIO_FIFO_ST_ROE_LSB _u(3)
#define SIO_FIFO_ST_ROE_ACCESS "WC"
// -----------------------------------------------------------------------------
// Field : SIO_FIFO_ST_WOF
// Description : Sticky flag indicating the TX FIFO was written when full. This
// write was ignored by the FIFO.
#define SIO_FIFO_ST_WOF_RESET _u(0x0)
#define SIO_FIFO_ST_WOF_BITS _u(0x00000004)
#define SIO_FIFO_ST_WOF_MSB _u(2)
#define SIO_FIFO_ST_WOF_LSB _u(2)
#define SIO_FIFO_ST_WOF_ACCESS "WC"
// -----------------------------------------------------------------------------
// Field : SIO_FIFO_ST_RDY
// Description : Value is 1 if this core's TX FIFO is not full (i.e. if FIFO_WR
// is ready for more data)
#define SIO_FIFO_ST_RDY_RESET _u(0x1)
#define SIO_FIFO_ST_RDY_BITS _u(0x00000002)
#define SIO_FIFO_ST_RDY_MSB _u(1)
#define SIO_FIFO_ST_RDY_LSB _u(1)
#define SIO_FIFO_ST_RDY_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_FIFO_ST_VLD
// Description : Value is 1 if this core's RX FIFO is not empty (i.e. if FIFO_RD
// is valid)
#define SIO_FIFO_ST_VLD_RESET _u(0x0)
#define SIO_FIFO_ST_VLD_BITS _u(0x00000001)
#define SIO_FIFO_ST_VLD_MSB _u(0)
#define SIO_FIFO_ST_VLD_LSB _u(0)
#define SIO_FIFO_ST_VLD_ACCESS "RO"
// =============================================================================
// Register : SIO_FIFO_WR
// Description : Write access to this core's TX FIFO
#define SIO_FIFO_WR_OFFSET _u(0x00000054)
#define SIO_FIFO_WR_BITS _u(0xffffffff)
#define SIO_FIFO_WR_RESET _u(0x00000000)
#define SIO_FIFO_WR_MSB _u(31)
#define SIO_FIFO_WR_LSB _u(0)
#define SIO_FIFO_WR_ACCESS "WF"
// =============================================================================
// Register : SIO_FIFO_RD
// Description : Read access to this core's RX FIFO
#define SIO_FIFO_RD_OFFSET _u(0x00000058)
#define SIO_FIFO_RD_BITS _u(0xffffffff)
#define SIO_FIFO_RD_RESET "-"
#define SIO_FIFO_RD_MSB _u(31)
#define SIO_FIFO_RD_LSB _u(0)
#define SIO_FIFO_RD_ACCESS "RF"
// =============================================================================
// Register : SIO_SPINLOCK_ST
// Description : Spinlock state
// A bitmap containing the state of all 32 spinlocks (1=locked).
// Mainly intended for debugging.
#define SIO_SPINLOCK_ST_OFFSET _u(0x0000005c)
#define SIO_SPINLOCK_ST_BITS _u(0xffffffff)
#define SIO_SPINLOCK_ST_RESET _u(0x00000000)
#define SIO_SPINLOCK_ST_MSB _u(31)
#define SIO_SPINLOCK_ST_LSB _u(0)
#define SIO_SPINLOCK_ST_ACCESS "RO"
// =============================================================================
// Register : SIO_DIV_UDIVIDEND
// Description : Divider unsigned dividend
// Write to the DIVIDEND operand of the divider, i.e. the p in `p
// / q`.
// Any operand write starts a new calculation. The results appear
// in QUOTIENT, REMAINDER.
// UDIVIDEND/SDIVIDEND are aliases of the same internal register.
// The U alias starts an
// unsigned calculation, and the S alias starts a signed
// calculation.
#define SIO_DIV_UDIVIDEND_OFFSET _u(0x00000060)
#define SIO_DIV_UDIVIDEND_BITS _u(0xffffffff)
#define SIO_DIV_UDIVIDEND_RESET _u(0x00000000)
#define SIO_DIV_UDIVIDEND_MSB _u(31)
#define SIO_DIV_UDIVIDEND_LSB _u(0)
#define SIO_DIV_UDIVIDEND_ACCESS "RW"
// =============================================================================
// Register : SIO_DIV_UDIVISOR
// Description : Divider unsigned divisor
// Write to the DIVISOR operand of the divider, i.e. the q in `p /
// q`.
// Any operand write starts a new calculation. The results appear
// in QUOTIENT, REMAINDER.
// UDIVIDEND/SDIVIDEND are aliases of the same internal register.
// The U alias starts an
// unsigned calculation, and the S alias starts a signed
// calculation.
#define SIO_DIV_UDIVISOR_OFFSET _u(0x00000064)
#define SIO_DIV_UDIVISOR_BITS _u(0xffffffff)
#define SIO_DIV_UDIVISOR_RESET _u(0x00000000)
#define SIO_DIV_UDIVISOR_MSB _u(31)
#define SIO_DIV_UDIVISOR_LSB _u(0)
#define SIO_DIV_UDIVISOR_ACCESS "RW"
// =============================================================================
// Register : SIO_DIV_SDIVIDEND
// Description : Divider signed dividend
// The same as UDIVIDEND, but starts a signed calculation, rather
// than unsigned.
#define SIO_DIV_SDIVIDEND_OFFSET _u(0x00000068)
#define SIO_DIV_SDIVIDEND_BITS _u(0xffffffff)
#define SIO_DIV_SDIVIDEND_RESET _u(0x00000000)
#define SIO_DIV_SDIVIDEND_MSB _u(31)
#define SIO_DIV_SDIVIDEND_LSB _u(0)
#define SIO_DIV_SDIVIDEND_ACCESS "RW"
// =============================================================================
// Register : SIO_DIV_SDIVISOR
// Description : Divider signed divisor
// The same as UDIVISOR, but starts a signed calculation, rather
// than unsigned.
#define SIO_DIV_SDIVISOR_OFFSET _u(0x0000006c)
#define SIO_DIV_SDIVISOR_BITS _u(0xffffffff)
#define SIO_DIV_SDIVISOR_RESET _u(0x00000000)
#define SIO_DIV_SDIVISOR_MSB _u(31)
#define SIO_DIV_SDIVISOR_LSB _u(0)
#define SIO_DIV_SDIVISOR_ACCESS "RW"
// =============================================================================
// Register : SIO_DIV_QUOTIENT
// Description : Divider result quotient
// The result of `DIVIDEND / DIVISOR` (division). Contents
// undefined while CSR_READY is low.
// For signed calculations, QUOTIENT is negative when the signs of
// DIVIDEND and DIVISOR differ.
// This register can be written to directly, for context
// save/restore purposes. This halts any
// in-progress calculation and sets the CSR_READY and CSR_DIRTY
// flags.
// Reading from QUOTIENT clears the CSR_DIRTY flag, so should read
// results in the order
// REMAINDER, QUOTIENT if CSR_DIRTY is used.
#define SIO_DIV_QUOTIENT_OFFSET _u(0x00000070)
#define SIO_DIV_QUOTIENT_BITS _u(0xffffffff)
#define SIO_DIV_QUOTIENT_RESET _u(0x00000000)
#define SIO_DIV_QUOTIENT_MSB _u(31)
#define SIO_DIV_QUOTIENT_LSB _u(0)
#define SIO_DIV_QUOTIENT_ACCESS "RW"
// =============================================================================
// Register : SIO_DIV_REMAINDER
// Description : Divider result remainder
// The result of `DIVIDEND % DIVISOR` (modulo). Contents undefined
// while CSR_READY is low.
// For signed calculations, REMAINDER is negative only when
// DIVIDEND is negative.
// This register can be written to directly, for context
// save/restore purposes. This halts any
// in-progress calculation and sets the CSR_READY and CSR_DIRTY
// flags.
#define SIO_DIV_REMAINDER_OFFSET _u(0x00000074)
#define SIO_DIV_REMAINDER_BITS _u(0xffffffff)
#define SIO_DIV_REMAINDER_RESET _u(0x00000000)
#define SIO_DIV_REMAINDER_MSB _u(31)
#define SIO_DIV_REMAINDER_LSB _u(0)
#define SIO_DIV_REMAINDER_ACCESS "RW"
// =============================================================================
// Register : SIO_DIV_CSR
// Description : Control and status register for divider.
#define SIO_DIV_CSR_OFFSET _u(0x00000078)
#define SIO_DIV_CSR_BITS _u(0x00000003)
#define SIO_DIV_CSR_RESET _u(0x00000001)
// -----------------------------------------------------------------------------
// Field : SIO_DIV_CSR_DIRTY
// Description : Changes to 1 when any register is written, and back to 0 when
// QUOTIENT is read.
// Software can use this flag to make save/restore more efficient
// (skip if not DIRTY).
// If the flag is used in this way, it's recommended to either
// read QUOTIENT only,
// or REMAINDER and then QUOTIENT, to prevent data loss on context
// switch.
#define SIO_DIV_CSR_DIRTY_RESET _u(0x0)
#define SIO_DIV_CSR_DIRTY_BITS _u(0x00000002)
#define SIO_DIV_CSR_DIRTY_MSB _u(1)
#define SIO_DIV_CSR_DIRTY_LSB _u(1)
#define SIO_DIV_CSR_DIRTY_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_DIV_CSR_READY
// Description : Reads as 0 when a calculation is in progress, 1 otherwise.
// Writing an operand (xDIVIDEND, xDIVISOR) will immediately start
// a new calculation, no
// matter if one is already in progress.
// Writing to a result register will immediately terminate any
// in-progress calculation
// and set the READY and DIRTY flags.
#define SIO_DIV_CSR_READY_RESET _u(0x1)
#define SIO_DIV_CSR_READY_BITS _u(0x00000001)
#define SIO_DIV_CSR_READY_MSB _u(0)
#define SIO_DIV_CSR_READY_LSB _u(0)
#define SIO_DIV_CSR_READY_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_ACCUM0
// Description : Read/write access to accumulator 0
#define SIO_INTERP0_ACCUM0_OFFSET _u(0x00000080)
#define SIO_INTERP0_ACCUM0_BITS _u(0xffffffff)
#define SIO_INTERP0_ACCUM0_RESET _u(0x00000000)
#define SIO_INTERP0_ACCUM0_MSB _u(31)
#define SIO_INTERP0_ACCUM0_LSB _u(0)
#define SIO_INTERP0_ACCUM0_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_ACCUM1
// Description : Read/write access to accumulator 1
#define SIO_INTERP0_ACCUM1_OFFSET _u(0x00000084)
#define SIO_INTERP0_ACCUM1_BITS _u(0xffffffff)
#define SIO_INTERP0_ACCUM1_RESET _u(0x00000000)
#define SIO_INTERP0_ACCUM1_MSB _u(31)
#define SIO_INTERP0_ACCUM1_LSB _u(0)
#define SIO_INTERP0_ACCUM1_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_BASE0
// Description : Read/write access to BASE0 register.
#define SIO_INTERP0_BASE0_OFFSET _u(0x00000088)
#define SIO_INTERP0_BASE0_BITS _u(0xffffffff)
#define SIO_INTERP0_BASE0_RESET _u(0x00000000)
#define SIO_INTERP0_BASE0_MSB _u(31)
#define SIO_INTERP0_BASE0_LSB _u(0)
#define SIO_INTERP0_BASE0_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_BASE1
// Description : Read/write access to BASE1 register.
#define SIO_INTERP0_BASE1_OFFSET _u(0x0000008c)
#define SIO_INTERP0_BASE1_BITS _u(0xffffffff)
#define SIO_INTERP0_BASE1_RESET _u(0x00000000)
#define SIO_INTERP0_BASE1_MSB _u(31)
#define SIO_INTERP0_BASE1_LSB _u(0)
#define SIO_INTERP0_BASE1_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_BASE2
// Description : Read/write access to BASE2 register.
#define SIO_INTERP0_BASE2_OFFSET _u(0x00000090)
#define SIO_INTERP0_BASE2_BITS _u(0xffffffff)
#define SIO_INTERP0_BASE2_RESET _u(0x00000000)
#define SIO_INTERP0_BASE2_MSB _u(31)
#define SIO_INTERP0_BASE2_LSB _u(0)
#define SIO_INTERP0_BASE2_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_POP_LANE0
// Description : Read LANE0 result, and simultaneously write lane results to
// both accumulators (POP).
#define SIO_INTERP0_POP_LANE0_OFFSET _u(0x00000094)
#define SIO_INTERP0_POP_LANE0_BITS _u(0xffffffff)
#define SIO_INTERP0_POP_LANE0_RESET _u(0x00000000)
#define SIO_INTERP0_POP_LANE0_MSB _u(31)
#define SIO_INTERP0_POP_LANE0_LSB _u(0)
#define SIO_INTERP0_POP_LANE0_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_POP_LANE1
// Description : Read LANE1 result, and simultaneously write lane results to
// both accumulators (POP).
#define SIO_INTERP0_POP_LANE1_OFFSET _u(0x00000098)
#define SIO_INTERP0_POP_LANE1_BITS _u(0xffffffff)
#define SIO_INTERP0_POP_LANE1_RESET _u(0x00000000)
#define SIO_INTERP0_POP_LANE1_MSB _u(31)
#define SIO_INTERP0_POP_LANE1_LSB _u(0)
#define SIO_INTERP0_POP_LANE1_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_POP_FULL
// Description : Read FULL result, and simultaneously write lane results to both
// accumulators (POP).
#define SIO_INTERP0_POP_FULL_OFFSET _u(0x0000009c)
#define SIO_INTERP0_POP_FULL_BITS _u(0xffffffff)
#define SIO_INTERP0_POP_FULL_RESET _u(0x00000000)
#define SIO_INTERP0_POP_FULL_MSB _u(31)
#define SIO_INTERP0_POP_FULL_LSB _u(0)
#define SIO_INTERP0_POP_FULL_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_PEEK_LANE0
// Description : Read LANE0 result, without altering any internal state (PEEK).
#define SIO_INTERP0_PEEK_LANE0_OFFSET _u(0x000000a0)
#define SIO_INTERP0_PEEK_LANE0_BITS _u(0xffffffff)
#define SIO_INTERP0_PEEK_LANE0_RESET _u(0x00000000)
#define SIO_INTERP0_PEEK_LANE0_MSB _u(31)
#define SIO_INTERP0_PEEK_LANE0_LSB _u(0)
#define SIO_INTERP0_PEEK_LANE0_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_PEEK_LANE1
// Description : Read LANE1 result, without altering any internal state (PEEK).
#define SIO_INTERP0_PEEK_LANE1_OFFSET _u(0x000000a4)
#define SIO_INTERP0_PEEK_LANE1_BITS _u(0xffffffff)
#define SIO_INTERP0_PEEK_LANE1_RESET _u(0x00000000)
#define SIO_INTERP0_PEEK_LANE1_MSB _u(31)
#define SIO_INTERP0_PEEK_LANE1_LSB _u(0)
#define SIO_INTERP0_PEEK_LANE1_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_PEEK_FULL
// Description : Read FULL result, without altering any internal state (PEEK).
#define SIO_INTERP0_PEEK_FULL_OFFSET _u(0x000000a8)
#define SIO_INTERP0_PEEK_FULL_BITS _u(0xffffffff)
#define SIO_INTERP0_PEEK_FULL_RESET _u(0x00000000)
#define SIO_INTERP0_PEEK_FULL_MSB _u(31)
#define SIO_INTERP0_PEEK_FULL_LSB _u(0)
#define SIO_INTERP0_PEEK_FULL_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP0_CTRL_LANE0
// Description : Control register for lane 0
#define SIO_INTERP0_CTRL_LANE0_OFFSET _u(0x000000ac)
#define SIO_INTERP0_CTRL_LANE0_BITS _u(0x03bfffff)
#define SIO_INTERP0_CTRL_LANE0_RESET _u(0x00000000)
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_OVERF
// Description : Set if either OVERF0 or OVERF1 is set.
#define SIO_INTERP0_CTRL_LANE0_OVERF_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_OVERF_BITS _u(0x02000000)
#define SIO_INTERP0_CTRL_LANE0_OVERF_MSB _u(25)
#define SIO_INTERP0_CTRL_LANE0_OVERF_LSB _u(25)
#define SIO_INTERP0_CTRL_LANE0_OVERF_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_OVERF1
// Description : Indicates if any masked-off MSBs in ACCUM1 are set.
#define SIO_INTERP0_CTRL_LANE0_OVERF1_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_OVERF1_BITS _u(0x01000000)
#define SIO_INTERP0_CTRL_LANE0_OVERF1_MSB _u(24)
#define SIO_INTERP0_CTRL_LANE0_OVERF1_LSB _u(24)
#define SIO_INTERP0_CTRL_LANE0_OVERF1_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_OVERF0
// Description : Indicates if any masked-off MSBs in ACCUM0 are set.
#define SIO_INTERP0_CTRL_LANE0_OVERF0_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_OVERF0_BITS _u(0x00800000)
#define SIO_INTERP0_CTRL_LANE0_OVERF0_MSB _u(23)
#define SIO_INTERP0_CTRL_LANE0_OVERF0_LSB _u(23)
#define SIO_INTERP0_CTRL_LANE0_OVERF0_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_BLEND
// Description : Only present on INTERP0 on each core. If BLEND mode is enabled:
// - LANE1 result is a linear interpolation between BASE0 and
// BASE1, controlled
// by the 8 LSBs of lane 1 shift and mask value (a fractional
// number between
// 0 and 255/256ths)
// - LANE0 result does not have BASE0 added (yields only the 8
// LSBs of lane 1 shift+mask value)
// - FULL result does not have lane 1 shift+mask value added
// (BASE2 + lane 0 shift+mask)
// LANE1 SIGNED flag controls whether the interpolation is signed
// or unsigned.
#define SIO_INTERP0_CTRL_LANE0_BLEND_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_BLEND_BITS _u(0x00200000)
#define SIO_INTERP0_CTRL_LANE0_BLEND_MSB _u(21)
#define SIO_INTERP0_CTRL_LANE0_BLEND_LSB _u(21)
#define SIO_INTERP0_CTRL_LANE0_BLEND_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_FORCE_MSB
// Description : ORed into bits 29:28 of the lane result presented to the
// processor on the bus.
// No effect on the internal 32-bit datapath. Handy for using a
// lane to generate sequence
// of pointers into flash or SRAM.
#define SIO_INTERP0_CTRL_LANE0_FORCE_MSB_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_FORCE_MSB_BITS _u(0x00180000)
#define SIO_INTERP0_CTRL_LANE0_FORCE_MSB_MSB _u(20)
#define SIO_INTERP0_CTRL_LANE0_FORCE_MSB_LSB _u(19)
#define SIO_INTERP0_CTRL_LANE0_FORCE_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_ADD_RAW
// Description : If 1, mask + shift is bypassed for LANE0 result. This does not
// affect FULL result.
#define SIO_INTERP0_CTRL_LANE0_ADD_RAW_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_ADD_RAW_BITS _u(0x00040000)
#define SIO_INTERP0_CTRL_LANE0_ADD_RAW_MSB _u(18)
#define SIO_INTERP0_CTRL_LANE0_ADD_RAW_LSB _u(18)
#define SIO_INTERP0_CTRL_LANE0_ADD_RAW_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_CROSS_RESULT
// Description : If 1, feed the opposite lane's result into this lane's
// accumulator on POP.
#define SIO_INTERP0_CTRL_LANE0_CROSS_RESULT_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_CROSS_RESULT_BITS _u(0x00020000)
#define SIO_INTERP0_CTRL_LANE0_CROSS_RESULT_MSB _u(17)
#define SIO_INTERP0_CTRL_LANE0_CROSS_RESULT_LSB _u(17)
#define SIO_INTERP0_CTRL_LANE0_CROSS_RESULT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_CROSS_INPUT
// Description : If 1, feed the opposite lane's accumulator into this lane's
// shift + mask hardware.
// Takes effect even if ADD_RAW is set (the CROSS_INPUT mux is
// before the shift+mask bypass)
#define SIO_INTERP0_CTRL_LANE0_CROSS_INPUT_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_CROSS_INPUT_BITS _u(0x00010000)
#define SIO_INTERP0_CTRL_LANE0_CROSS_INPUT_MSB _u(16)
#define SIO_INTERP0_CTRL_LANE0_CROSS_INPUT_LSB _u(16)
#define SIO_INTERP0_CTRL_LANE0_CROSS_INPUT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_SIGNED
// Description : If SIGNED is set, the shifted and masked accumulator value is
// sign-extended to 32 bits
// before adding to BASE0, and LANE0 PEEK/POP appear extended to
// 32 bits when read by processor.
#define SIO_INTERP0_CTRL_LANE0_SIGNED_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE0_SIGNED_BITS _u(0x00008000)
#define SIO_INTERP0_CTRL_LANE0_SIGNED_MSB _u(15)
#define SIO_INTERP0_CTRL_LANE0_SIGNED_LSB _u(15)
#define SIO_INTERP0_CTRL_LANE0_SIGNED_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_MASK_MSB
// Description : The most-significant bit allowed to pass by the mask
// (inclusive)
// Setting MSB < LSB may cause chip to turn inside-out
#define SIO_INTERP0_CTRL_LANE0_MASK_MSB_RESET _u(0x00)
#define SIO_INTERP0_CTRL_LANE0_MASK_MSB_BITS _u(0x00007c00)
#define SIO_INTERP0_CTRL_LANE0_MASK_MSB_MSB _u(14)
#define SIO_INTERP0_CTRL_LANE0_MASK_MSB_LSB _u(10)
#define SIO_INTERP0_CTRL_LANE0_MASK_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_MASK_LSB
// Description : The least-significant bit allowed to pass by the mask
// (inclusive)
#define SIO_INTERP0_CTRL_LANE0_MASK_LSB_RESET _u(0x00)
#define SIO_INTERP0_CTRL_LANE0_MASK_LSB_BITS _u(0x000003e0)
#define SIO_INTERP0_CTRL_LANE0_MASK_LSB_MSB _u(9)
#define SIO_INTERP0_CTRL_LANE0_MASK_LSB_LSB _u(5)
#define SIO_INTERP0_CTRL_LANE0_MASK_LSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE0_SHIFT
// Description : Logical right-shift applied to accumulator before masking
#define SIO_INTERP0_CTRL_LANE0_SHIFT_RESET _u(0x00)
#define SIO_INTERP0_CTRL_LANE0_SHIFT_BITS _u(0x0000001f)
#define SIO_INTERP0_CTRL_LANE0_SHIFT_MSB _u(4)
#define SIO_INTERP0_CTRL_LANE0_SHIFT_LSB _u(0)
#define SIO_INTERP0_CTRL_LANE0_SHIFT_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_CTRL_LANE1
// Description : Control register for lane 1
#define SIO_INTERP0_CTRL_LANE1_OFFSET _u(0x000000b0)
#define SIO_INTERP0_CTRL_LANE1_BITS _u(0x001fffff)
#define SIO_INTERP0_CTRL_LANE1_RESET _u(0x00000000)
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_FORCE_MSB
// Description : ORed into bits 29:28 of the lane result presented to the
// processor on the bus.
// No effect on the internal 32-bit datapath. Handy for using a
// lane to generate sequence
// of pointers into flash or SRAM.
#define SIO_INTERP0_CTRL_LANE1_FORCE_MSB_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE1_FORCE_MSB_BITS _u(0x00180000)
#define SIO_INTERP0_CTRL_LANE1_FORCE_MSB_MSB _u(20)
#define SIO_INTERP0_CTRL_LANE1_FORCE_MSB_LSB _u(19)
#define SIO_INTERP0_CTRL_LANE1_FORCE_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_ADD_RAW
// Description : If 1, mask + shift is bypassed for LANE1 result. This does not
// affect FULL result.
#define SIO_INTERP0_CTRL_LANE1_ADD_RAW_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE1_ADD_RAW_BITS _u(0x00040000)
#define SIO_INTERP0_CTRL_LANE1_ADD_RAW_MSB _u(18)
#define SIO_INTERP0_CTRL_LANE1_ADD_RAW_LSB _u(18)
#define SIO_INTERP0_CTRL_LANE1_ADD_RAW_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_CROSS_RESULT
// Description : If 1, feed the opposite lane's result into this lane's
// accumulator on POP.
#define SIO_INTERP0_CTRL_LANE1_CROSS_RESULT_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE1_CROSS_RESULT_BITS _u(0x00020000)
#define SIO_INTERP0_CTRL_LANE1_CROSS_RESULT_MSB _u(17)
#define SIO_INTERP0_CTRL_LANE1_CROSS_RESULT_LSB _u(17)
#define SIO_INTERP0_CTRL_LANE1_CROSS_RESULT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_CROSS_INPUT
// Description : If 1, feed the opposite lane's accumulator into this lane's
// shift + mask hardware.
// Takes effect even if ADD_RAW is set (the CROSS_INPUT mux is
// before the shift+mask bypass)
#define SIO_INTERP0_CTRL_LANE1_CROSS_INPUT_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE1_CROSS_INPUT_BITS _u(0x00010000)
#define SIO_INTERP0_CTRL_LANE1_CROSS_INPUT_MSB _u(16)
#define SIO_INTERP0_CTRL_LANE1_CROSS_INPUT_LSB _u(16)
#define SIO_INTERP0_CTRL_LANE1_CROSS_INPUT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_SIGNED
// Description : If SIGNED is set, the shifted and masked accumulator value is
// sign-extended to 32 bits
// before adding to BASE1, and LANE1 PEEK/POP appear extended to
// 32 bits when read by processor.
#define SIO_INTERP0_CTRL_LANE1_SIGNED_RESET _u(0x0)
#define SIO_INTERP0_CTRL_LANE1_SIGNED_BITS _u(0x00008000)
#define SIO_INTERP0_CTRL_LANE1_SIGNED_MSB _u(15)
#define SIO_INTERP0_CTRL_LANE1_SIGNED_LSB _u(15)
#define SIO_INTERP0_CTRL_LANE1_SIGNED_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_MASK_MSB
// Description : The most-significant bit allowed to pass by the mask
// (inclusive)
// Setting MSB < LSB may cause chip to turn inside-out
#define SIO_INTERP0_CTRL_LANE1_MASK_MSB_RESET _u(0x00)
#define SIO_INTERP0_CTRL_LANE1_MASK_MSB_BITS _u(0x00007c00)
#define SIO_INTERP0_CTRL_LANE1_MASK_MSB_MSB _u(14)
#define SIO_INTERP0_CTRL_LANE1_MASK_MSB_LSB _u(10)
#define SIO_INTERP0_CTRL_LANE1_MASK_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_MASK_LSB
// Description : The least-significant bit allowed to pass by the mask
// (inclusive)
#define SIO_INTERP0_CTRL_LANE1_MASK_LSB_RESET _u(0x00)
#define SIO_INTERP0_CTRL_LANE1_MASK_LSB_BITS _u(0x000003e0)
#define SIO_INTERP0_CTRL_LANE1_MASK_LSB_MSB _u(9)
#define SIO_INTERP0_CTRL_LANE1_MASK_LSB_LSB _u(5)
#define SIO_INTERP0_CTRL_LANE1_MASK_LSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP0_CTRL_LANE1_SHIFT
// Description : Logical right-shift applied to accumulator before masking
#define SIO_INTERP0_CTRL_LANE1_SHIFT_RESET _u(0x00)
#define SIO_INTERP0_CTRL_LANE1_SHIFT_BITS _u(0x0000001f)
#define SIO_INTERP0_CTRL_LANE1_SHIFT_MSB _u(4)
#define SIO_INTERP0_CTRL_LANE1_SHIFT_LSB _u(0)
#define SIO_INTERP0_CTRL_LANE1_SHIFT_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_ACCUM0_ADD
// Description : Values written here are atomically added to ACCUM0
// Reading yields lane 0's raw shift and mask value (BASE0 not
// added).
#define SIO_INTERP0_ACCUM0_ADD_OFFSET _u(0x000000b4)
#define SIO_INTERP0_ACCUM0_ADD_BITS _u(0x00ffffff)
#define SIO_INTERP0_ACCUM0_ADD_RESET _u(0x00000000)
#define SIO_INTERP0_ACCUM0_ADD_MSB _u(23)
#define SIO_INTERP0_ACCUM0_ADD_LSB _u(0)
#define SIO_INTERP0_ACCUM0_ADD_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_ACCUM1_ADD
// Description : Values written here are atomically added to ACCUM1
// Reading yields lane 1's raw shift and mask value (BASE1 not
// added).
#define SIO_INTERP0_ACCUM1_ADD_OFFSET _u(0x000000b8)
#define SIO_INTERP0_ACCUM1_ADD_BITS _u(0x00ffffff)
#define SIO_INTERP0_ACCUM1_ADD_RESET _u(0x00000000)
#define SIO_INTERP0_ACCUM1_ADD_MSB _u(23)
#define SIO_INTERP0_ACCUM1_ADD_LSB _u(0)
#define SIO_INTERP0_ACCUM1_ADD_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP0_BASE_1AND0
// Description : On write, the lower 16 bits go to BASE0, upper bits to BASE1
// simultaneously.
// Each half is sign-extended to 32 bits if that lane's SIGNED
// flag is set.
#define SIO_INTERP0_BASE_1AND0_OFFSET _u(0x000000bc)
#define SIO_INTERP0_BASE_1AND0_BITS _u(0xffffffff)
#define SIO_INTERP0_BASE_1AND0_RESET _u(0x00000000)
#define SIO_INTERP0_BASE_1AND0_MSB _u(31)
#define SIO_INTERP0_BASE_1AND0_LSB _u(0)
#define SIO_INTERP0_BASE_1AND0_ACCESS "WO"
// =============================================================================
// Register : SIO_INTERP1_ACCUM0
// Description : Read/write access to accumulator 0
#define SIO_INTERP1_ACCUM0_OFFSET _u(0x000000c0)
#define SIO_INTERP1_ACCUM0_BITS _u(0xffffffff)
#define SIO_INTERP1_ACCUM0_RESET _u(0x00000000)
#define SIO_INTERP1_ACCUM0_MSB _u(31)
#define SIO_INTERP1_ACCUM0_LSB _u(0)
#define SIO_INTERP1_ACCUM0_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_ACCUM1
// Description : Read/write access to accumulator 1
#define SIO_INTERP1_ACCUM1_OFFSET _u(0x000000c4)
#define SIO_INTERP1_ACCUM1_BITS _u(0xffffffff)
#define SIO_INTERP1_ACCUM1_RESET _u(0x00000000)
#define SIO_INTERP1_ACCUM1_MSB _u(31)
#define SIO_INTERP1_ACCUM1_LSB _u(0)
#define SIO_INTERP1_ACCUM1_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_BASE0
// Description : Read/write access to BASE0 register.
#define SIO_INTERP1_BASE0_OFFSET _u(0x000000c8)
#define SIO_INTERP1_BASE0_BITS _u(0xffffffff)
#define SIO_INTERP1_BASE0_RESET _u(0x00000000)
#define SIO_INTERP1_BASE0_MSB _u(31)
#define SIO_INTERP1_BASE0_LSB _u(0)
#define SIO_INTERP1_BASE0_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_BASE1
// Description : Read/write access to BASE1 register.
#define SIO_INTERP1_BASE1_OFFSET _u(0x000000cc)
#define SIO_INTERP1_BASE1_BITS _u(0xffffffff)
#define SIO_INTERP1_BASE1_RESET _u(0x00000000)
#define SIO_INTERP1_BASE1_MSB _u(31)
#define SIO_INTERP1_BASE1_LSB _u(0)
#define SIO_INTERP1_BASE1_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_BASE2
// Description : Read/write access to BASE2 register.
#define SIO_INTERP1_BASE2_OFFSET _u(0x000000d0)
#define SIO_INTERP1_BASE2_BITS _u(0xffffffff)
#define SIO_INTERP1_BASE2_RESET _u(0x00000000)
#define SIO_INTERP1_BASE2_MSB _u(31)
#define SIO_INTERP1_BASE2_LSB _u(0)
#define SIO_INTERP1_BASE2_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_POP_LANE0
// Description : Read LANE0 result, and simultaneously write lane results to
// both accumulators (POP).
#define SIO_INTERP1_POP_LANE0_OFFSET _u(0x000000d4)
#define SIO_INTERP1_POP_LANE0_BITS _u(0xffffffff)
#define SIO_INTERP1_POP_LANE0_RESET _u(0x00000000)
#define SIO_INTERP1_POP_LANE0_MSB _u(31)
#define SIO_INTERP1_POP_LANE0_LSB _u(0)
#define SIO_INTERP1_POP_LANE0_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP1_POP_LANE1
// Description : Read LANE1 result, and simultaneously write lane results to
// both accumulators (POP).
#define SIO_INTERP1_POP_LANE1_OFFSET _u(0x000000d8)
#define SIO_INTERP1_POP_LANE1_BITS _u(0xffffffff)
#define SIO_INTERP1_POP_LANE1_RESET _u(0x00000000)
#define SIO_INTERP1_POP_LANE1_MSB _u(31)
#define SIO_INTERP1_POP_LANE1_LSB _u(0)
#define SIO_INTERP1_POP_LANE1_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP1_POP_FULL
// Description : Read FULL result, and simultaneously write lane results to both
// accumulators (POP).
#define SIO_INTERP1_POP_FULL_OFFSET _u(0x000000dc)
#define SIO_INTERP1_POP_FULL_BITS _u(0xffffffff)
#define SIO_INTERP1_POP_FULL_RESET _u(0x00000000)
#define SIO_INTERP1_POP_FULL_MSB _u(31)
#define SIO_INTERP1_POP_FULL_LSB _u(0)
#define SIO_INTERP1_POP_FULL_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP1_PEEK_LANE0
// Description : Read LANE0 result, without altering any internal state (PEEK).
#define SIO_INTERP1_PEEK_LANE0_OFFSET _u(0x000000e0)
#define SIO_INTERP1_PEEK_LANE0_BITS _u(0xffffffff)
#define SIO_INTERP1_PEEK_LANE0_RESET _u(0x00000000)
#define SIO_INTERP1_PEEK_LANE0_MSB _u(31)
#define SIO_INTERP1_PEEK_LANE0_LSB _u(0)
#define SIO_INTERP1_PEEK_LANE0_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP1_PEEK_LANE1
// Description : Read LANE1 result, without altering any internal state (PEEK).
#define SIO_INTERP1_PEEK_LANE1_OFFSET _u(0x000000e4)
#define SIO_INTERP1_PEEK_LANE1_BITS _u(0xffffffff)
#define SIO_INTERP1_PEEK_LANE1_RESET _u(0x00000000)
#define SIO_INTERP1_PEEK_LANE1_MSB _u(31)
#define SIO_INTERP1_PEEK_LANE1_LSB _u(0)
#define SIO_INTERP1_PEEK_LANE1_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP1_PEEK_FULL
// Description : Read FULL result, without altering any internal state (PEEK).
#define SIO_INTERP1_PEEK_FULL_OFFSET _u(0x000000e8)
#define SIO_INTERP1_PEEK_FULL_BITS _u(0xffffffff)
#define SIO_INTERP1_PEEK_FULL_RESET _u(0x00000000)
#define SIO_INTERP1_PEEK_FULL_MSB _u(31)
#define SIO_INTERP1_PEEK_FULL_LSB _u(0)
#define SIO_INTERP1_PEEK_FULL_ACCESS "RO"
// =============================================================================
// Register : SIO_INTERP1_CTRL_LANE0
// Description : Control register for lane 0
#define SIO_INTERP1_CTRL_LANE0_OFFSET _u(0x000000ec)
#define SIO_INTERP1_CTRL_LANE0_BITS _u(0x03dfffff)
#define SIO_INTERP1_CTRL_LANE0_RESET _u(0x00000000)
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_OVERF
// Description : Set if either OVERF0 or OVERF1 is set.
#define SIO_INTERP1_CTRL_LANE0_OVERF_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_OVERF_BITS _u(0x02000000)
#define SIO_INTERP1_CTRL_LANE0_OVERF_MSB _u(25)
#define SIO_INTERP1_CTRL_LANE0_OVERF_LSB _u(25)
#define SIO_INTERP1_CTRL_LANE0_OVERF_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_OVERF1
// Description : Indicates if any masked-off MSBs in ACCUM1 are set.
#define SIO_INTERP1_CTRL_LANE0_OVERF1_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_OVERF1_BITS _u(0x01000000)
#define SIO_INTERP1_CTRL_LANE0_OVERF1_MSB _u(24)
#define SIO_INTERP1_CTRL_LANE0_OVERF1_LSB _u(24)
#define SIO_INTERP1_CTRL_LANE0_OVERF1_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_OVERF0
// Description : Indicates if any masked-off MSBs in ACCUM0 are set.
#define SIO_INTERP1_CTRL_LANE0_OVERF0_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_OVERF0_BITS _u(0x00800000)
#define SIO_INTERP1_CTRL_LANE0_OVERF0_MSB _u(23)
#define SIO_INTERP1_CTRL_LANE0_OVERF0_LSB _u(23)
#define SIO_INTERP1_CTRL_LANE0_OVERF0_ACCESS "RO"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_CLAMP
// Description : Only present on INTERP1 on each core. If CLAMP mode is enabled:
// - LANE0 result is shifted and masked ACCUM0, clamped by a lower
// bound of
// BASE0 and an upper bound of BASE1.
// - Signedness of these comparisons is determined by
// LANE0_CTRL_SIGNED
#define SIO_INTERP1_CTRL_LANE0_CLAMP_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_CLAMP_BITS _u(0x00400000)
#define SIO_INTERP1_CTRL_LANE0_CLAMP_MSB _u(22)
#define SIO_INTERP1_CTRL_LANE0_CLAMP_LSB _u(22)
#define SIO_INTERP1_CTRL_LANE0_CLAMP_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_FORCE_MSB
// Description : ORed into bits 29:28 of the lane result presented to the
// processor on the bus.
// No effect on the internal 32-bit datapath. Handy for using a
// lane to generate sequence
// of pointers into flash or SRAM.
#define SIO_INTERP1_CTRL_LANE0_FORCE_MSB_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_FORCE_MSB_BITS _u(0x00180000)
#define SIO_INTERP1_CTRL_LANE0_FORCE_MSB_MSB _u(20)
#define SIO_INTERP1_CTRL_LANE0_FORCE_MSB_LSB _u(19)
#define SIO_INTERP1_CTRL_LANE0_FORCE_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_ADD_RAW
// Description : If 1, mask + shift is bypassed for LANE0 result. This does not
// affect FULL result.
#define SIO_INTERP1_CTRL_LANE0_ADD_RAW_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_ADD_RAW_BITS _u(0x00040000)
#define SIO_INTERP1_CTRL_LANE0_ADD_RAW_MSB _u(18)
#define SIO_INTERP1_CTRL_LANE0_ADD_RAW_LSB _u(18)
#define SIO_INTERP1_CTRL_LANE0_ADD_RAW_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_CROSS_RESULT
// Description : If 1, feed the opposite lane's result into this lane's
// accumulator on POP.
#define SIO_INTERP1_CTRL_LANE0_CROSS_RESULT_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_CROSS_RESULT_BITS _u(0x00020000)
#define SIO_INTERP1_CTRL_LANE0_CROSS_RESULT_MSB _u(17)
#define SIO_INTERP1_CTRL_LANE0_CROSS_RESULT_LSB _u(17)
#define SIO_INTERP1_CTRL_LANE0_CROSS_RESULT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_CROSS_INPUT
// Description : If 1, feed the opposite lane's accumulator into this lane's
// shift + mask hardware.
// Takes effect even if ADD_RAW is set (the CROSS_INPUT mux is
// before the shift+mask bypass)
#define SIO_INTERP1_CTRL_LANE0_CROSS_INPUT_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_CROSS_INPUT_BITS _u(0x00010000)
#define SIO_INTERP1_CTRL_LANE0_CROSS_INPUT_MSB _u(16)
#define SIO_INTERP1_CTRL_LANE0_CROSS_INPUT_LSB _u(16)
#define SIO_INTERP1_CTRL_LANE0_CROSS_INPUT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_SIGNED
// Description : If SIGNED is set, the shifted and masked accumulator value is
// sign-extended to 32 bits
// before adding to BASE0, and LANE0 PEEK/POP appear extended to
// 32 bits when read by processor.
#define SIO_INTERP1_CTRL_LANE0_SIGNED_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE0_SIGNED_BITS _u(0x00008000)
#define SIO_INTERP1_CTRL_LANE0_SIGNED_MSB _u(15)
#define SIO_INTERP1_CTRL_LANE0_SIGNED_LSB _u(15)
#define SIO_INTERP1_CTRL_LANE0_SIGNED_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_MASK_MSB
// Description : The most-significant bit allowed to pass by the mask
// (inclusive)
// Setting MSB < LSB may cause chip to turn inside-out
#define SIO_INTERP1_CTRL_LANE0_MASK_MSB_RESET _u(0x00)
#define SIO_INTERP1_CTRL_LANE0_MASK_MSB_BITS _u(0x00007c00)
#define SIO_INTERP1_CTRL_LANE0_MASK_MSB_MSB _u(14)
#define SIO_INTERP1_CTRL_LANE0_MASK_MSB_LSB _u(10)
#define SIO_INTERP1_CTRL_LANE0_MASK_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_MASK_LSB
// Description : The least-significant bit allowed to pass by the mask
// (inclusive)
#define SIO_INTERP1_CTRL_LANE0_MASK_LSB_RESET _u(0x00)
#define SIO_INTERP1_CTRL_LANE0_MASK_LSB_BITS _u(0x000003e0)
#define SIO_INTERP1_CTRL_LANE0_MASK_LSB_MSB _u(9)
#define SIO_INTERP1_CTRL_LANE0_MASK_LSB_LSB _u(5)
#define SIO_INTERP1_CTRL_LANE0_MASK_LSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE0_SHIFT
// Description : Logical right-shift applied to accumulator before masking
#define SIO_INTERP1_CTRL_LANE0_SHIFT_RESET _u(0x00)
#define SIO_INTERP1_CTRL_LANE0_SHIFT_BITS _u(0x0000001f)
#define SIO_INTERP1_CTRL_LANE0_SHIFT_MSB _u(4)
#define SIO_INTERP1_CTRL_LANE0_SHIFT_LSB _u(0)
#define SIO_INTERP1_CTRL_LANE0_SHIFT_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_CTRL_LANE1
// Description : Control register for lane 1
#define SIO_INTERP1_CTRL_LANE1_OFFSET _u(0x000000f0)
#define SIO_INTERP1_CTRL_LANE1_BITS _u(0x001fffff)
#define SIO_INTERP1_CTRL_LANE1_RESET _u(0x00000000)
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_FORCE_MSB
// Description : ORed into bits 29:28 of the lane result presented to the
// processor on the bus.
// No effect on the internal 32-bit datapath. Handy for using a
// lane to generate sequence
// of pointers into flash or SRAM.
#define SIO_INTERP1_CTRL_LANE1_FORCE_MSB_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE1_FORCE_MSB_BITS _u(0x00180000)
#define SIO_INTERP1_CTRL_LANE1_FORCE_MSB_MSB _u(20)
#define SIO_INTERP1_CTRL_LANE1_FORCE_MSB_LSB _u(19)
#define SIO_INTERP1_CTRL_LANE1_FORCE_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_ADD_RAW
// Description : If 1, mask + shift is bypassed for LANE1 result. This does not
// affect FULL result.
#define SIO_INTERP1_CTRL_LANE1_ADD_RAW_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE1_ADD_RAW_BITS _u(0x00040000)
#define SIO_INTERP1_CTRL_LANE1_ADD_RAW_MSB _u(18)
#define SIO_INTERP1_CTRL_LANE1_ADD_RAW_LSB _u(18)
#define SIO_INTERP1_CTRL_LANE1_ADD_RAW_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_CROSS_RESULT
// Description : If 1, feed the opposite lane's result into this lane's
// accumulator on POP.
#define SIO_INTERP1_CTRL_LANE1_CROSS_RESULT_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE1_CROSS_RESULT_BITS _u(0x00020000)
#define SIO_INTERP1_CTRL_LANE1_CROSS_RESULT_MSB _u(17)
#define SIO_INTERP1_CTRL_LANE1_CROSS_RESULT_LSB _u(17)
#define SIO_INTERP1_CTRL_LANE1_CROSS_RESULT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_CROSS_INPUT
// Description : If 1, feed the opposite lane's accumulator into this lane's
// shift + mask hardware.
// Takes effect even if ADD_RAW is set (the CROSS_INPUT mux is
// before the shift+mask bypass)
#define SIO_INTERP1_CTRL_LANE1_CROSS_INPUT_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE1_CROSS_INPUT_BITS _u(0x00010000)
#define SIO_INTERP1_CTRL_LANE1_CROSS_INPUT_MSB _u(16)
#define SIO_INTERP1_CTRL_LANE1_CROSS_INPUT_LSB _u(16)
#define SIO_INTERP1_CTRL_LANE1_CROSS_INPUT_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_SIGNED
// Description : If SIGNED is set, the shifted and masked accumulator value is
// sign-extended to 32 bits
// before adding to BASE1, and LANE1 PEEK/POP appear extended to
// 32 bits when read by processor.
#define SIO_INTERP1_CTRL_LANE1_SIGNED_RESET _u(0x0)
#define SIO_INTERP1_CTRL_LANE1_SIGNED_BITS _u(0x00008000)
#define SIO_INTERP1_CTRL_LANE1_SIGNED_MSB _u(15)
#define SIO_INTERP1_CTRL_LANE1_SIGNED_LSB _u(15)
#define SIO_INTERP1_CTRL_LANE1_SIGNED_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_MASK_MSB
// Description : The most-significant bit allowed to pass by the mask
// (inclusive)
// Setting MSB < LSB may cause chip to turn inside-out
#define SIO_INTERP1_CTRL_LANE1_MASK_MSB_RESET _u(0x00)
#define SIO_INTERP1_CTRL_LANE1_MASK_MSB_BITS _u(0x00007c00)
#define SIO_INTERP1_CTRL_LANE1_MASK_MSB_MSB _u(14)
#define SIO_INTERP1_CTRL_LANE1_MASK_MSB_LSB _u(10)
#define SIO_INTERP1_CTRL_LANE1_MASK_MSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_MASK_LSB
// Description : The least-significant bit allowed to pass by the mask
// (inclusive)
#define SIO_INTERP1_CTRL_LANE1_MASK_LSB_RESET _u(0x00)
#define SIO_INTERP1_CTRL_LANE1_MASK_LSB_BITS _u(0x000003e0)
#define SIO_INTERP1_CTRL_LANE1_MASK_LSB_MSB _u(9)
#define SIO_INTERP1_CTRL_LANE1_MASK_LSB_LSB _u(5)
#define SIO_INTERP1_CTRL_LANE1_MASK_LSB_ACCESS "RW"
// -----------------------------------------------------------------------------
// Field : SIO_INTERP1_CTRL_LANE1_SHIFT
// Description : Logical right-shift applied to accumulator before masking
#define SIO_INTERP1_CTRL_LANE1_SHIFT_RESET _u(0x00)
#define SIO_INTERP1_CTRL_LANE1_SHIFT_BITS _u(0x0000001f)
#define SIO_INTERP1_CTRL_LANE1_SHIFT_MSB _u(4)
#define SIO_INTERP1_CTRL_LANE1_SHIFT_LSB _u(0)
#define SIO_INTERP1_CTRL_LANE1_SHIFT_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_ACCUM0_ADD
// Description : Values written here are atomically added to ACCUM0
// Reading yields lane 0's raw shift and mask value (BASE0 not
// added).
#define SIO_INTERP1_ACCUM0_ADD_OFFSET _u(0x000000f4)
#define SIO_INTERP1_ACCUM0_ADD_BITS _u(0x00ffffff)
#define SIO_INTERP1_ACCUM0_ADD_RESET _u(0x00000000)
#define SIO_INTERP1_ACCUM0_ADD_MSB _u(23)
#define SIO_INTERP1_ACCUM0_ADD_LSB _u(0)
#define SIO_INTERP1_ACCUM0_ADD_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_ACCUM1_ADD
// Description : Values written here are atomically added to ACCUM1
// Reading yields lane 1's raw shift and mask value (BASE1 not
// added).
#define SIO_INTERP1_ACCUM1_ADD_OFFSET _u(0x000000f8)
#define SIO_INTERP1_ACCUM1_ADD_BITS _u(0x00ffffff)
#define SIO_INTERP1_ACCUM1_ADD_RESET _u(0x00000000)
#define SIO_INTERP1_ACCUM1_ADD_MSB _u(23)
#define SIO_INTERP1_ACCUM1_ADD_LSB _u(0)
#define SIO_INTERP1_ACCUM1_ADD_ACCESS "RW"
// =============================================================================
// Register : SIO_INTERP1_BASE_1AND0
// Description : On write, the lower 16 bits go to BASE0, upper bits to BASE1
// simultaneously.
// Each half is sign-extended to 32 bits if that lane's SIGNED
// flag is set.
#define SIO_INTERP1_BASE_1AND0_OFFSET _u(0x000000fc)
#define SIO_INTERP1_BASE_1AND0_BITS _u(0xffffffff)
#define SIO_INTERP1_BASE_1AND0_RESET _u(0x00000000)
#define SIO_INTERP1_BASE_1AND0_MSB _u(31)
#define SIO_INTERP1_BASE_1AND0_LSB _u(0)
#define SIO_INTERP1_BASE_1AND0_ACCESS "WO"
// =============================================================================
// Register : SIO_SPINLOCK0
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK0_OFFSET _u(0x00000100)
#define SIO_SPINLOCK0_BITS _u(0xffffffff)
#define SIO_SPINLOCK0_RESET _u(0x00000000)
#define SIO_SPINLOCK0_MSB _u(31)
#define SIO_SPINLOCK0_LSB _u(0)
#define SIO_SPINLOCK0_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK1
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK1_OFFSET _u(0x00000104)
#define SIO_SPINLOCK1_BITS _u(0xffffffff)
#define SIO_SPINLOCK1_RESET _u(0x00000000)
#define SIO_SPINLOCK1_MSB _u(31)
#define SIO_SPINLOCK1_LSB _u(0)
#define SIO_SPINLOCK1_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK2
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK2_OFFSET _u(0x00000108)
#define SIO_SPINLOCK2_BITS _u(0xffffffff)
#define SIO_SPINLOCK2_RESET _u(0x00000000)
#define SIO_SPINLOCK2_MSB _u(31)
#define SIO_SPINLOCK2_LSB _u(0)
#define SIO_SPINLOCK2_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK3
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK3_OFFSET _u(0x0000010c)
#define SIO_SPINLOCK3_BITS _u(0xffffffff)
#define SIO_SPINLOCK3_RESET _u(0x00000000)
#define SIO_SPINLOCK3_MSB _u(31)
#define SIO_SPINLOCK3_LSB _u(0)
#define SIO_SPINLOCK3_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK4
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK4_OFFSET _u(0x00000110)
#define SIO_SPINLOCK4_BITS _u(0xffffffff)
#define SIO_SPINLOCK4_RESET _u(0x00000000)
#define SIO_SPINLOCK4_MSB _u(31)
#define SIO_SPINLOCK4_LSB _u(0)
#define SIO_SPINLOCK4_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK5
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK5_OFFSET _u(0x00000114)
#define SIO_SPINLOCK5_BITS _u(0xffffffff)
#define SIO_SPINLOCK5_RESET _u(0x00000000)
#define SIO_SPINLOCK5_MSB _u(31)
#define SIO_SPINLOCK5_LSB _u(0)
#define SIO_SPINLOCK5_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK6
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK6_OFFSET _u(0x00000118)
#define SIO_SPINLOCK6_BITS _u(0xffffffff)
#define SIO_SPINLOCK6_RESET _u(0x00000000)
#define SIO_SPINLOCK6_MSB _u(31)
#define SIO_SPINLOCK6_LSB _u(0)
#define SIO_SPINLOCK6_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK7
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK7_OFFSET _u(0x0000011c)
#define SIO_SPINLOCK7_BITS _u(0xffffffff)
#define SIO_SPINLOCK7_RESET _u(0x00000000)
#define SIO_SPINLOCK7_MSB _u(31)
#define SIO_SPINLOCK7_LSB _u(0)
#define SIO_SPINLOCK7_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK8
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK8_OFFSET _u(0x00000120)
#define SIO_SPINLOCK8_BITS _u(0xffffffff)
#define SIO_SPINLOCK8_RESET _u(0x00000000)
#define SIO_SPINLOCK8_MSB _u(31)
#define SIO_SPINLOCK8_LSB _u(0)
#define SIO_SPINLOCK8_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK9
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK9_OFFSET _u(0x00000124)
#define SIO_SPINLOCK9_BITS _u(0xffffffff)
#define SIO_SPINLOCK9_RESET _u(0x00000000)
#define SIO_SPINLOCK9_MSB _u(31)
#define SIO_SPINLOCK9_LSB _u(0)
#define SIO_SPINLOCK9_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK10
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK10_OFFSET _u(0x00000128)
#define SIO_SPINLOCK10_BITS _u(0xffffffff)
#define SIO_SPINLOCK10_RESET _u(0x00000000)
#define SIO_SPINLOCK10_MSB _u(31)
#define SIO_SPINLOCK10_LSB _u(0)
#define SIO_SPINLOCK10_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK11
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK11_OFFSET _u(0x0000012c)
#define SIO_SPINLOCK11_BITS _u(0xffffffff)
#define SIO_SPINLOCK11_RESET _u(0x00000000)
#define SIO_SPINLOCK11_MSB _u(31)
#define SIO_SPINLOCK11_LSB _u(0)
#define SIO_SPINLOCK11_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK12
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK12_OFFSET _u(0x00000130)
#define SIO_SPINLOCK12_BITS _u(0xffffffff)
#define SIO_SPINLOCK12_RESET _u(0x00000000)
#define SIO_SPINLOCK12_MSB _u(31)
#define SIO_SPINLOCK12_LSB _u(0)
#define SIO_SPINLOCK12_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK13
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK13_OFFSET _u(0x00000134)
#define SIO_SPINLOCK13_BITS _u(0xffffffff)
#define SIO_SPINLOCK13_RESET _u(0x00000000)
#define SIO_SPINLOCK13_MSB _u(31)
#define SIO_SPINLOCK13_LSB _u(0)
#define SIO_SPINLOCK13_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK14
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK14_OFFSET _u(0x00000138)
#define SIO_SPINLOCK14_BITS _u(0xffffffff)
#define SIO_SPINLOCK14_RESET _u(0x00000000)
#define SIO_SPINLOCK14_MSB _u(31)
#define SIO_SPINLOCK14_LSB _u(0)
#define SIO_SPINLOCK14_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK15
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK15_OFFSET _u(0x0000013c)
#define SIO_SPINLOCK15_BITS _u(0xffffffff)
#define SIO_SPINLOCK15_RESET _u(0x00000000)
#define SIO_SPINLOCK15_MSB _u(31)
#define SIO_SPINLOCK15_LSB _u(0)
#define SIO_SPINLOCK15_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK16
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK16_OFFSET _u(0x00000140)
#define SIO_SPINLOCK16_BITS _u(0xffffffff)
#define SIO_SPINLOCK16_RESET _u(0x00000000)
#define SIO_SPINLOCK16_MSB _u(31)
#define SIO_SPINLOCK16_LSB _u(0)
#define SIO_SPINLOCK16_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK17
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK17_OFFSET _u(0x00000144)
#define SIO_SPINLOCK17_BITS _u(0xffffffff)
#define SIO_SPINLOCK17_RESET _u(0x00000000)
#define SIO_SPINLOCK17_MSB _u(31)
#define SIO_SPINLOCK17_LSB _u(0)
#define SIO_SPINLOCK17_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK18
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK18_OFFSET _u(0x00000148)
#define SIO_SPINLOCK18_BITS _u(0xffffffff)
#define SIO_SPINLOCK18_RESET _u(0x00000000)
#define SIO_SPINLOCK18_MSB _u(31)
#define SIO_SPINLOCK18_LSB _u(0)
#define SIO_SPINLOCK18_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK19
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK19_OFFSET _u(0x0000014c)
#define SIO_SPINLOCK19_BITS _u(0xffffffff)
#define SIO_SPINLOCK19_RESET _u(0x00000000)
#define SIO_SPINLOCK19_MSB _u(31)
#define SIO_SPINLOCK19_LSB _u(0)
#define SIO_SPINLOCK19_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK20
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK20_OFFSET _u(0x00000150)
#define SIO_SPINLOCK20_BITS _u(0xffffffff)
#define SIO_SPINLOCK20_RESET _u(0x00000000)
#define SIO_SPINLOCK20_MSB _u(31)
#define SIO_SPINLOCK20_LSB _u(0)
#define SIO_SPINLOCK20_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK21
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK21_OFFSET _u(0x00000154)
#define SIO_SPINLOCK21_BITS _u(0xffffffff)
#define SIO_SPINLOCK21_RESET _u(0x00000000)
#define SIO_SPINLOCK21_MSB _u(31)
#define SIO_SPINLOCK21_LSB _u(0)
#define SIO_SPINLOCK21_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK22
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK22_OFFSET _u(0x00000158)
#define SIO_SPINLOCK22_BITS _u(0xffffffff)
#define SIO_SPINLOCK22_RESET _u(0x00000000)
#define SIO_SPINLOCK22_MSB _u(31)
#define SIO_SPINLOCK22_LSB _u(0)
#define SIO_SPINLOCK22_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK23
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK23_OFFSET _u(0x0000015c)
#define SIO_SPINLOCK23_BITS _u(0xffffffff)
#define SIO_SPINLOCK23_RESET _u(0x00000000)
#define SIO_SPINLOCK23_MSB _u(31)
#define SIO_SPINLOCK23_LSB _u(0)
#define SIO_SPINLOCK23_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK24
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK24_OFFSET _u(0x00000160)
#define SIO_SPINLOCK24_BITS _u(0xffffffff)
#define SIO_SPINLOCK24_RESET _u(0x00000000)
#define SIO_SPINLOCK24_MSB _u(31)
#define SIO_SPINLOCK24_LSB _u(0)
#define SIO_SPINLOCK24_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK25
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK25_OFFSET _u(0x00000164)
#define SIO_SPINLOCK25_BITS _u(0xffffffff)
#define SIO_SPINLOCK25_RESET _u(0x00000000)
#define SIO_SPINLOCK25_MSB _u(31)
#define SIO_SPINLOCK25_LSB _u(0)
#define SIO_SPINLOCK25_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK26
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK26_OFFSET _u(0x00000168)
#define SIO_SPINLOCK26_BITS _u(0xffffffff)
#define SIO_SPINLOCK26_RESET _u(0x00000000)
#define SIO_SPINLOCK26_MSB _u(31)
#define SIO_SPINLOCK26_LSB _u(0)
#define SIO_SPINLOCK26_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK27
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK27_OFFSET _u(0x0000016c)
#define SIO_SPINLOCK27_BITS _u(0xffffffff)
#define SIO_SPINLOCK27_RESET _u(0x00000000)
#define SIO_SPINLOCK27_MSB _u(31)
#define SIO_SPINLOCK27_LSB _u(0)
#define SIO_SPINLOCK27_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK28
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK28_OFFSET _u(0x00000170)
#define SIO_SPINLOCK28_BITS _u(0xffffffff)
#define SIO_SPINLOCK28_RESET _u(0x00000000)
#define SIO_SPINLOCK28_MSB _u(31)
#define SIO_SPINLOCK28_LSB _u(0)
#define SIO_SPINLOCK28_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK29
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK29_OFFSET _u(0x00000174)
#define SIO_SPINLOCK29_BITS _u(0xffffffff)
#define SIO_SPINLOCK29_RESET _u(0x00000000)
#define SIO_SPINLOCK29_MSB _u(31)
#define SIO_SPINLOCK29_LSB _u(0)
#define SIO_SPINLOCK29_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK30
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK30_OFFSET _u(0x00000178)
#define SIO_SPINLOCK30_BITS _u(0xffffffff)
#define SIO_SPINLOCK30_RESET _u(0x00000000)
#define SIO_SPINLOCK30_MSB _u(31)
#define SIO_SPINLOCK30_LSB _u(0)
#define SIO_SPINLOCK30_ACCESS "RO"
// =============================================================================
// Register : SIO_SPINLOCK31
// Description : Reading from a spinlock address will:
// - Return 0 if lock is already locked
// - Otherwise return nonzero, and simultaneously claim the lock
//
// Writing (any value) releases the lock.
// If core 0 and core 1 attempt to claim the same lock
// simultaneously, core 0 wins.
// The value returned on success is 0x1 << lock number.
#define SIO_SPINLOCK31_OFFSET _u(0x0000017c)
#define SIO_SPINLOCK31_BITS _u(0xffffffff)
#define SIO_SPINLOCK31_RESET _u(0x00000000)
#define SIO_SPINLOCK31_MSB _u(31)
#define SIO_SPINLOCK31_LSB _u(0)
#define SIO_SPINLOCK31_ACCESS "RO"
// =============================================================================
#endif // HARDWARE_REGS_SIO_DEFINED