sw/device/lib/dif/autogen/dif_kmac_autogen.c - 3p/lowrisc/opentitan - Git at Google

 // Copyright lowRISC contributors.
 // Licensed under the Apache License, Version 2.0, see LICENSE for details.
 // SPDX-License-Identifier: Apache-2.0

 // This file is auto-generated.

 #include "sw/device/lib/dif/autogen/dif_kmac_autogen.h"

 #include "kmac_regs.h"  // Generated.

 /**
  * Get the corresponding interrupt register bit offset of the IRQ. If the IP's
  * HJSON does NOT have a field "no_auto_intr_regs = true", then the
  * "<ip>_INTR_COMMON_<irq>_BIT" macro can used. Otherwise, special cases will
  * exist, as templated below.
  */
 static bool kmac_get_irq_bit_index(dif_kmac_irq_t irq,
                                    bitfield_bit32_index_t *index_out) {
   switch (irq) {
     case kDifKmacIrqKmacDone:
       *index_out = KMAC_INTR_COMMON_KMAC_DONE_BIT;
       break;
     case kDifKmacIrqFifoEmpty:
       *index_out = KMAC_INTR_COMMON_FIFO_EMPTY_BIT;
       break;
     case kDifKmacIrqKmacErr:
       *index_out = KMAC_INTR_COMMON_KMAC_ERR_BIT;
       break;
     default:
       return false;
   }

   return true;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_get_state(const dif_kmac_t *kmac,
                                     dif_kmac_irq_state_snapshot_t *snapshot) {
   if (kmac == NULL || snapshot == NULL) {
     return kDifBadArg;
   }

   *snapshot = mmio_region_read32(kmac->base_addr, KMAC_INTR_STATE_REG_OFFSET);

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_is_pending(const dif_kmac_t *kmac, dif_kmac_irq_t irq,
                                      bool *is_pending) {
   if (kmac == NULL || is_pending == NULL) {
     return kDifBadArg;
   }

   bitfield_bit32_index_t index;
   if (!kmac_get_irq_bit_index(irq, &index)) {
     return kDifBadArg;
   }

   uint32_t intr_state_reg =
       mmio_region_read32(kmac->base_addr, KMAC_INTR_STATE_REG_OFFSET);

   *is_pending = bitfield_bit32_read(intr_state_reg, index);

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_acknowledge(const dif_kmac_t *kmac,
                                       dif_kmac_irq_t irq) {
   if (kmac == NULL) {
     return kDifBadArg;
   }

   bitfield_bit32_index_t index;
   if (!kmac_get_irq_bit_index(irq, &index)) {
     return kDifBadArg;
   }

   // Writing to the register clears the corresponding bits (Write-one clear).
   uint32_t intr_state_reg = bitfield_bit32_write(0, index, true);
   mmio_region_write32(kmac->base_addr, KMAC_INTR_STATE_REG_OFFSET,
                       intr_state_reg);

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_force(const dif_kmac_t *kmac, dif_kmac_irq_t irq) {
   if (kmac == NULL) {
     return kDifBadArg;
   }

   bitfield_bit32_index_t index;
   if (!kmac_get_irq_bit_index(irq, &index)) {
     return kDifBadArg;
   }

   uint32_t intr_test_reg = bitfield_bit32_write(0, index, true);
   mmio_region_write32(kmac->base_addr, KMAC_INTR_TEST_REG_OFFSET,
                       intr_test_reg);

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_get_enabled(const dif_kmac_t *kmac,
                                       dif_kmac_irq_t irq, dif_toggle_t *state) {
   if (kmac == NULL || state == NULL) {
     return kDifBadArg;
   }

   bitfield_bit32_index_t index;
   if (!kmac_get_irq_bit_index(irq, &index)) {
     return kDifBadArg;
   }

   uint32_t intr_enable_reg =
       mmio_region_read32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET);

   bool is_enabled = bitfield_bit32_read(intr_enable_reg, index);
   *state = is_enabled ? kDifToggleEnabled : kDifToggleDisabled;

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_set_enabled(const dif_kmac_t *kmac,
                                       dif_kmac_irq_t irq, dif_toggle_t state) {
   if (kmac == NULL) {
     return kDifBadArg;
   }

   bitfield_bit32_index_t index;
   if (!kmac_get_irq_bit_index(irq, &index)) {
     return kDifBadArg;
   }

   uint32_t intr_enable_reg =
       mmio_region_read32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET);

   bool enable_bit = (state == kDifToggleEnabled) ? true : false;
   intr_enable_reg = bitfield_bit32_write(intr_enable_reg, index, enable_bit);
   mmio_region_write32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET,
                       intr_enable_reg);

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_disable_all(
     const dif_kmac_t *kmac, dif_kmac_irq_enable_snapshot_t *snapshot) {
   if (kmac == NULL) {
     return kDifBadArg;
   }

   // Pass the current interrupt state to the caller, if requested.
   if (snapshot != NULL) {
     *snapshot =
         mmio_region_read32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET);
   }

   // Disable all interrupts.
   mmio_region_write32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET, 0u);

   return kDifOk;
 }

 OT_WARN_UNUSED_RESULT
 dif_result_t dif_kmac_irq_restore_all(
     const dif_kmac_t *kmac, const dif_kmac_irq_enable_snapshot_t *snapshot) {
   if (kmac == NULL || snapshot == NULL) {
     return kDifBadArg;
   }

   mmio_region_write32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET, *snapshot);

   return kDifOk;
 }
	// Copyright lowRISC contributors.
	// Licensed under the Apache License, Version 2.0, see LICENSE for details.
	// SPDX-License-Identifier: Apache-2.0

	// This file is auto-generated.

	#include "sw/device/lib/dif/autogen/dif_kmac_autogen.h"

	#include "kmac_regs.h" // Generated.

	/**
	* Get the corresponding interrupt register bit offset of the IRQ. If the IP's
	* HJSON does NOT have a field "no_auto_intr_regs = true", then the
	* "<ip>_INTR_COMMON_<irq>_BIT" macro can used. Otherwise, special cases will
	* exist, as templated below.
	*/
	static bool kmac_get_irq_bit_index(dif_kmac_irq_t irq,
	bitfield_bit32_index_t *index_out) {
	switch (irq) {
	case kDifKmacIrqKmacDone:
	*index_out = KMAC_INTR_COMMON_KMAC_DONE_BIT;
	break;
	case kDifKmacIrqFifoEmpty:
	*index_out = KMAC_INTR_COMMON_FIFO_EMPTY_BIT;
	break;
	case kDifKmacIrqKmacErr:
	*index_out = KMAC_INTR_COMMON_KMAC_ERR_BIT;
	break;
	default:
	return false;
	}

	return true;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_get_state(const dif_kmac_t *kmac,
	dif_kmac_irq_state_snapshot_t *snapshot) {
	if (kmac == NULL \|\| snapshot == NULL) {
	return kDifBadArg;
	}

	*snapshot = mmio_region_read32(kmac->base_addr, KMAC_INTR_STATE_REG_OFFSET);

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_is_pending(const dif_kmac_t *kmac, dif_kmac_irq_t irq,
	bool *is_pending) {
	if (kmac == NULL \|\| is_pending == NULL) {
	return kDifBadArg;
	}

	bitfield_bit32_index_t index;
	if (!kmac_get_irq_bit_index(irq, &index)) {
	return kDifBadArg;
	}

	uint32_t intr_state_reg =
	mmio_region_read32(kmac->base_addr, KMAC_INTR_STATE_REG_OFFSET);

	*is_pending = bitfield_bit32_read(intr_state_reg, index);

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_acknowledge(const dif_kmac_t *kmac,
	dif_kmac_irq_t irq) {
	if (kmac == NULL) {
	return kDifBadArg;
	}

	bitfield_bit32_index_t index;
	if (!kmac_get_irq_bit_index(irq, &index)) {
	return kDifBadArg;
	}

	// Writing to the register clears the corresponding bits (Write-one clear).
	uint32_t intr_state_reg = bitfield_bit32_write(0, index, true);
	mmio_region_write32(kmac->base_addr, KMAC_INTR_STATE_REG_OFFSET,
	intr_state_reg);

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_force(const dif_kmac_t *kmac, dif_kmac_irq_t irq) {
	if (kmac == NULL) {
	return kDifBadArg;
	}

	bitfield_bit32_index_t index;
	if (!kmac_get_irq_bit_index(irq, &index)) {
	return kDifBadArg;
	}

	uint32_t intr_test_reg = bitfield_bit32_write(0, index, true);
	mmio_region_write32(kmac->base_addr, KMAC_INTR_TEST_REG_OFFSET,
	intr_test_reg);

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_get_enabled(const dif_kmac_t *kmac,
	dif_kmac_irq_t irq, dif_toggle_t *state) {
	if (kmac == NULL \|\| state == NULL) {
	return kDifBadArg;
	}

	bitfield_bit32_index_t index;
	if (!kmac_get_irq_bit_index(irq, &index)) {
	return kDifBadArg;
	}

	uint32_t intr_enable_reg =
	mmio_region_read32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET);

	bool is_enabled = bitfield_bit32_read(intr_enable_reg, index);
	*state = is_enabled ? kDifToggleEnabled : kDifToggleDisabled;

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_set_enabled(const dif_kmac_t *kmac,
	dif_kmac_irq_t irq, dif_toggle_t state) {
	if (kmac == NULL) {
	return kDifBadArg;
	}

	bitfield_bit32_index_t index;
	if (!kmac_get_irq_bit_index(irq, &index)) {
	return kDifBadArg;
	}

	uint32_t intr_enable_reg =
	mmio_region_read32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET);

	bool enable_bit = (state == kDifToggleEnabled) ? true : false;
	intr_enable_reg = bitfield_bit32_write(intr_enable_reg, index, enable_bit);
	mmio_region_write32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET,
	intr_enable_reg);

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_disable_all(
	const dif_kmac_t kmac, dif_kmac_irq_enable_snapshot_t snapshot) {
	if (kmac == NULL) {
	return kDifBadArg;
	}

	// Pass the current interrupt state to the caller, if requested.
	if (snapshot != NULL) {
	*snapshot =
	mmio_region_read32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET);
	}

	// Disable all interrupts.
	mmio_region_write32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET, 0u);

	return kDifOk;
	}

	OT_WARN_UNUSED_RESULT
	dif_result_t dif_kmac_irq_restore_all(
	const dif_kmac_t kmac, const dif_kmac_irq_enable_snapshot_t snapshot) {
	if (kmac == NULL \|\| snapshot == NULL) {
	return kDifBadArg;
	}

	mmio_region_write32(kmac->base_addr, KMAC_INTR_ENABLE_REG_OFFSET, *snapshot);

	return kDifOk;
	}