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linux/drivers/gpu/nova-core/regs.rs
Joel Fernandes 4a4d4e320a gpu: nova-core: Add code comments related to devinit 
Add several code comments to reduce acronym soup and explain how devinit
magic and bootflow works before driver loads. These are essential for
debug and development of the nova driver.

[acourbot@nvidia.com: reformat and reword a couple of sentences]

Signed-off-by: Joel Fernandes <joelagnelf@nvidia.com>
Signed-off-by: Alexandre Courbot <acourbot@nvidia.com>
Link: https://lore.kernel.org/r/20250708-nova-docs-v4-1-9d188772c4c7@nvidia.com
Signed-off-by: Danilo Krummrich <dakr@kernel.org>
2025-07-09 00:07:34 +02:00

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// SPDX-License-Identifier: GPL-2.0
// Required to retain the original register names used by OpenRM, which are all capital snake case
// but are mapped to types.
#![allow(non_camel_case_types)]
#[macro_use]
mod macros;
use crate::falcon::{
DmaTrfCmdSize, FalconCoreRev, FalconCoreRevSubversion, FalconFbifMemType, FalconFbifTarget,
FalconModSelAlgo, FalconSecurityModel, PeregrineCoreSelect,
};
use crate::gpu::{Architecture, Chipset};
use kernel::prelude::*;
/* PMC */
register!(NV_PMC_BOOT_0 @ 0x00000000, "Basic revision information about the GPU" {
3:0 minor_revision as u8, "Minor revision of the chip";
7:4 major_revision as u8, "Major revision of the chip";
8:8 architecture_1 as u8, "MSB of the architecture";
23:20 implementation as u8, "Implementation version of the architecture";
28:24 architecture_0 as u8, "Lower bits of the architecture";
});
impl NV_PMC_BOOT_0 {
/// Combines `architecture_0` and `architecture_1` to obtain the architecture of the chip.
pub(crate) fn architecture(self) -> Result<Architecture> {
Architecture::try_from(
self.architecture_0() | (self.architecture_1() << Self::ARCHITECTURE_0.len()),
)
}
/// Combines `architecture` and `implementation` to obtain a code unique to the chipset.
pub(crate) fn chipset(self) -> Result<Chipset> {
self.architecture()
.map(|arch| {
((arch as u32) << Self::IMPLEMENTATION.len()) | self.implementation() as u32
})
.and_then(Chipset::try_from)
}
}
/* PBUS */
// TODO[REGA]: this is an array of registers.
register!(NV_PBUS_SW_SCRATCH_0E@0x00001438 {
31:16 frts_err_code as u16;
});
/* PFB */
register!(NV_PFB_NISO_FLUSH_SYSMEM_ADDR @ 0x00100c10 {
31:0 adr_39_08 as u32;
});
register!(NV_PFB_NISO_FLUSH_SYSMEM_ADDR_HI @ 0x00100c40 {
23:0 adr_63_40 as u32;
});
register!(NV_PFB_PRI_MMU_LOCAL_MEMORY_RANGE @ 0x00100ce0 {
3:0 lower_scale as u8;
9:4 lower_mag as u8;
30:30 ecc_mode_enabled as bool;
});
impl NV_PFB_PRI_MMU_LOCAL_MEMORY_RANGE {
/// Returns the usable framebuffer size, in bytes.
pub(crate) fn usable_fb_size(self) -> u64 {
let size = (u64::from(self.lower_mag()) << u64::from(self.lower_scale()))
* kernel::sizes::SZ_1M as u64;
if self.ecc_mode_enabled() {
// Remove the amount of memory reserved for ECC (one per 16 units).
size / 16 * 15
} else {
size
}
}
}
register!(NV_PFB_PRI_MMU_WPR2_ADDR_LO@0x001fa824 {
31:4 lo_val as u32, "Bits 12..40 of the lower (inclusive) bound of the WPR2 region";
});
impl NV_PFB_PRI_MMU_WPR2_ADDR_LO {
/// Returns the lower (inclusive) bound of the WPR2 region.
pub(crate) fn lower_bound(self) -> u64 {
u64::from(self.lo_val()) << 12
}
}
register!(NV_PFB_PRI_MMU_WPR2_ADDR_HI@0x001fa828 {
31:4 hi_val as u32, "Bits 12..40 of the higher (exclusive) bound of the WPR2 region";
});
impl NV_PFB_PRI_MMU_WPR2_ADDR_HI {
/// Returns the higher (exclusive) bound of the WPR2 region.
///
/// A value of zero means the WPR2 region is not set.
pub(crate) fn higher_bound(self) -> u64 {
u64::from(self.hi_val()) << 12
}
}
// PGC6 register space.
//
// `GC6` is a GPU low-power state where VRAM is in self-refresh and the GPU is powered down (except
// for power rails needed to keep self-refresh working and important registers and hardware
// blocks).
//
// These scratch registers remain powered on even in a low-power state and have a designated group
// number.
// Privilege level mask register. It dictates whether the host CPU has privilege to access the
// `PGC6_AON_SECURE_SCRATCH_GROUP_05` register (which it needs to read GFW_BOOT).
register!(NV_PGC6_AON_SECURE_SCRATCH_GROUP_05_PRIV_LEVEL_MASK @ 0x00118128,
"Privilege level mask register" {
0:0 read_protection_level0 as bool, "Set after FWSEC lowers its protection level";
});
// TODO[REGA]: This is an array of registers.
register!(NV_PGC6_AON_SECURE_SCRATCH_GROUP_05 @ 0x00118234 {
31:0 value as u32;
});
register!(
NV_PGC6_AON_SECURE_SCRATCH_GROUP_05_0_GFW_BOOT => NV_PGC6_AON_SECURE_SCRATCH_GROUP_05,
"Scratch group 05 register 0 used as GFW boot progress indicator" {
7:0 progress as u8, "Progress of GFW boot (0xff means completed)";
}
);
impl NV_PGC6_AON_SECURE_SCRATCH_GROUP_05_0_GFW_BOOT {
/// Returns `true` if GFW boot is completed.
pub(crate) fn completed(self) -> bool {
self.progress() == 0xff
}
}
register!(NV_PGC6_AON_SECURE_SCRATCH_GROUP_42 @ 0x001183a4 {
31:0 value as u32;
});
register!(
NV_USABLE_FB_SIZE_IN_MB => NV_PGC6_AON_SECURE_SCRATCH_GROUP_42,
"Scratch group 42 register used as framebuffer size" {
31:0 value as u32, "Usable framebuffer size, in megabytes";
}
);
impl NV_USABLE_FB_SIZE_IN_MB {
/// Returns the usable framebuffer size, in bytes.
pub(crate) fn usable_fb_size(self) -> u64 {
u64::from(self.value()) * kernel::sizes::SZ_1M as u64
}
}
/* PDISP */
register!(NV_PDISP_VGA_WORKSPACE_BASE @ 0x00625f04 {
3:3 status_valid as bool, "Set if the `addr` field is valid";
31:8 addr as u32, "VGA workspace base address divided by 0x10000";
});
impl NV_PDISP_VGA_WORKSPACE_BASE {
/// Returns the base address of the VGA workspace, or `None` if none exists.
pub(crate) fn vga_workspace_addr(self) -> Option<u64> {
if self.status_valid() {
Some(u64::from(self.addr()) << 16)
} else {
None
}
}
}
/* FUSE */
register!(NV_FUSE_OPT_FPF_NVDEC_UCODE1_VERSION @ 0x00824100 {
15:0 data as u16;
});
register!(NV_FUSE_OPT_FPF_SEC2_UCODE1_VERSION @ 0x00824140 {
15:0 data as u16;
});
register!(NV_FUSE_OPT_FPF_GSP_UCODE1_VERSION @ 0x008241c0 {
15:0 data as u16;
});
/* PFALCON */
register!(NV_PFALCON_FALCON_IRQSCLR @ +0x00000004 {
4:4 halt as bool;
6:6 swgen0 as bool;
});
register!(NV_PFALCON_FALCON_MAILBOX0 @ +0x00000040 {
31:0 value as u32;
});
register!(NV_PFALCON_FALCON_MAILBOX1 @ +0x00000044 {
31:0 value as u32;
});
register!(NV_PFALCON_FALCON_RM @ +0x00000084 {
31:0 value as u32;
});
register!(NV_PFALCON_FALCON_HWCFG2 @ +0x000000f4 {
10:10 riscv as bool;
12:12 mem_scrubbing as bool, "Set to 0 after memory scrubbing is completed";
31:31 reset_ready as bool, "Signal indicating that reset is completed (GA102+)";
});
impl NV_PFALCON_FALCON_HWCFG2 {
/// Returns `true` if memory scrubbing is completed.
pub(crate) fn mem_scrubbing_done(self) -> bool {
!self.mem_scrubbing()
}
}
register!(NV_PFALCON_FALCON_CPUCTL @ +0x00000100 {
1:1 startcpu as bool;
4:4 halted as bool;
6:6 alias_en as bool;
});
register!(NV_PFALCON_FALCON_BOOTVEC @ +0x00000104 {
31:0 value as u32;
});
register!(NV_PFALCON_FALCON_DMACTL @ +0x0000010c {
0:0 require_ctx as bool;
1:1 dmem_scrubbing as bool;
2:2 imem_scrubbing as bool;
6:3 dmaq_num as u8;
7:7 secure_stat as bool;
});
register!(NV_PFALCON_FALCON_DMATRFBASE @ +0x00000110 {
31:0 base as u32;
});
register!(NV_PFALCON_FALCON_DMATRFMOFFS @ +0x00000114 {
23:0 offs as u32;
});
register!(NV_PFALCON_FALCON_DMATRFCMD @ +0x00000118 {
0:0 full as bool;
1:1 idle as bool;
3:2 sec as u8;
4:4 imem as bool;
5:5 is_write as bool;
10:8 size as u8 ?=> DmaTrfCmdSize;
14:12 ctxdma as u8;
16:16 set_dmtag as u8;
});
register!(NV_PFALCON_FALCON_DMATRFFBOFFS @ +0x0000011c {
31:0 offs as u32;
});
register!(NV_PFALCON_FALCON_DMATRFBASE1 @ +0x00000128 {
8:0 base as u16;
});
register!(NV_PFALCON_FALCON_HWCFG1 @ +0x0000012c {
3:0 core_rev as u8 ?=> FalconCoreRev, "Core revision";
5:4 security_model as u8 ?=> FalconSecurityModel, "Security model";
7:6 core_rev_subversion as u8 ?=> FalconCoreRevSubversion, "Core revision subversion";
});
register!(NV_PFALCON_FALCON_CPUCTL_ALIAS @ +0x00000130 {
1:1 startcpu as bool;
});
// Actually known as `NV_PSEC_FALCON_ENGINE` and `NV_PGSP_FALCON_ENGINE` depending on the falcon
// instance.
register!(NV_PFALCON_FALCON_ENGINE @ +0x000003c0 {
0:0 reset as bool;
});
// TODO[REGA]: this is an array of registers.
register!(NV_PFALCON_FBIF_TRANSCFG @ +0x00000600 {
1:0 target as u8 ?=> FalconFbifTarget;
2:2 mem_type as bool => FalconFbifMemType;
});
register!(NV_PFALCON_FBIF_CTL @ +0x00000624 {
7:7 allow_phys_no_ctx as bool;
});
register!(NV_PFALCON2_FALCON_MOD_SEL @ +0x00001180 {
7:0 algo as u8 ?=> FalconModSelAlgo;
});
register!(NV_PFALCON2_FALCON_BROM_CURR_UCODE_ID @ +0x00001198 {
7:0 ucode_id as u8;
});
register!(NV_PFALCON2_FALCON_BROM_ENGIDMASK @ +0x0000119c {
31:0 value as u32;
});
// TODO[REGA]: this is an array of registers.
register!(NV_PFALCON2_FALCON_BROM_PARAADDR @ +0x00001210 {
31:0 value as u32;
});
/* PRISCV */
register!(NV_PRISCV_RISCV_BCR_CTRL @ +0x00001668 {
0:0 valid as bool;
4:4 core_select as bool => PeregrineCoreSelect;
8:8 br_fetch as bool;
});
// The modules below provide registers that are not identical on all supported chips. They should
// only be used in HAL modules.
pub(crate) mod gm107 {
/* FUSE */
register!(NV_FUSE_STATUS_OPT_DISPLAY @ 0x00021c04 {
0:0 display_disabled as bool;
});
}
pub(crate) mod ga100 {
/* FUSE */
register!(NV_FUSE_STATUS_OPT_DISPLAY @ 0x00820c04 {
0:0 display_disabled as bool;
});
}
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