1 // SPDX-License-Identifier: GPL-2.0 2 3 // Required to retain the original register names used by OpenRM, which are all capital snake case 4 // but are mapped to types. 5 #![allow(non_camel_case_types)] 6 7 #[macro_use] 8 pub(crate) mod macros; 9 10 use kernel::prelude::*; 11 12 use crate::{ 13 falcon::{ 14 DmaTrfCmdSize, 15 FalconCoreRev, 16 FalconCoreRevSubversion, 17 FalconFbifMemType, 18 FalconFbifTarget, 19 FalconModSelAlgo, 20 FalconSecurityModel, 21 PFalcon2Base, 22 PFalconBase, 23 PeregrineCoreSelect, // 24 }, 25 gpu::{ 26 Architecture, 27 Chipset, // 28 }, 29 num::FromSafeCast, 30 }; 31 32 // PMC 33 34 register!(NV_PMC_BOOT_0 @ 0x00000000, "Basic revision information about the GPU" { 35 3:0 minor_revision as u8, "Minor revision of the chip"; 36 7:4 major_revision as u8, "Major revision of the chip"; 37 8:8 architecture_1 as u8, "MSB of the architecture"; 38 23:20 implementation as u8, "Implementation version of the architecture"; 39 28:24 architecture_0 as u8, "Lower bits of the architecture"; 40 }); 41 42 impl NV_PMC_BOOT_0 { 43 /// Combines `architecture_0` and `architecture_1` to obtain the architecture of the chip. 44 pub(crate) fn architecture(self) -> Result<Architecture> { 45 Architecture::try_from( 46 self.architecture_0() | (self.architecture_1() << Self::ARCHITECTURE_0_RANGE.len()), 47 ) 48 } 49 50 /// Combines `architecture` and `implementation` to obtain a code unique to the chipset. 51 pub(crate) fn chipset(self) -> Result<Chipset> { 52 self.architecture() 53 .map(|arch| { 54 ((arch as u32) << Self::IMPLEMENTATION_RANGE.len()) 55 | u32::from(self.implementation()) 56 }) 57 .and_then(Chipset::try_from) 58 } 59 } 60 61 // PBUS 62 63 register!(NV_PBUS_SW_SCRATCH @ 0x00001400[64] {}); 64 65 register!(NV_PBUS_SW_SCRATCH_0E_FRTS_ERR => NV_PBUS_SW_SCRATCH[0xe], 66 "scratch register 0xe used as FRTS firmware error code" { 67 31:16 frts_err_code as u16; 68 }); 69 70 // PFB 71 72 // The following two registers together hold the physical system memory address that is used by the 73 // GPU to perform sysmembar operations (see `fb::SysmemFlush`). 74 75 register!(NV_PFB_NISO_FLUSH_SYSMEM_ADDR @ 0x00100c10 { 76 31:0 adr_39_08 as u32; 77 }); 78 79 register!(NV_PFB_NISO_FLUSH_SYSMEM_ADDR_HI @ 0x00100c40 { 80 23:0 adr_63_40 as u32; 81 }); 82 83 register!(NV_PFB_PRI_MMU_LOCAL_MEMORY_RANGE @ 0x00100ce0 { 84 3:0 lower_scale as u8; 85 9:4 lower_mag as u8; 86 30:30 ecc_mode_enabled as bool; 87 }); 88 89 register!(NV_PGSP_QUEUE_HEAD @ 0x00110c00 { 90 31:0 address as u32; 91 }); 92 93 impl NV_PFB_PRI_MMU_LOCAL_MEMORY_RANGE { 94 /// Returns the usable framebuffer size, in bytes. 95 pub(crate) fn usable_fb_size(self) -> u64 { 96 let size = (u64::from(self.lower_mag()) << u64::from(self.lower_scale())) 97 * u64::from_safe_cast(kernel::sizes::SZ_1M); 98 99 if self.ecc_mode_enabled() { 100 // Remove the amount of memory reserved for ECC (one per 16 units). 101 size / 16 * 15 102 } else { 103 size 104 } 105 } 106 } 107 108 register!(NV_PFB_PRI_MMU_WPR2_ADDR_LO@0x001fa824 { 109 31:4 lo_val as u32, "Bits 12..40 of the lower (inclusive) bound of the WPR2 region"; 110 }); 111 112 impl NV_PFB_PRI_MMU_WPR2_ADDR_LO { 113 /// Returns the lower (inclusive) bound of the WPR2 region. 114 pub(crate) fn lower_bound(self) -> u64 { 115 u64::from(self.lo_val()) << 12 116 } 117 } 118 119 register!(NV_PFB_PRI_MMU_WPR2_ADDR_HI@0x001fa828 { 120 31:4 hi_val as u32, "Bits 12..40 of the higher (exclusive) bound of the WPR2 region"; 121 }); 122 123 impl NV_PFB_PRI_MMU_WPR2_ADDR_HI { 124 /// Returns the higher (exclusive) bound of the WPR2 region. 125 /// 126 /// A value of zero means the WPR2 region is not set. 127 pub(crate) fn higher_bound(self) -> u64 { 128 u64::from(self.hi_val()) << 12 129 } 130 } 131 132 // PGC6 register space. 133 // 134 // `GC6` is a GPU low-power state where VRAM is in self-refresh and the GPU is powered down (except 135 // for power rails needed to keep self-refresh working and important registers and hardware 136 // blocks). 137 // 138 // These scratch registers remain powered on even in a low-power state and have a designated group 139 // number. 140 141 // Privilege level mask register. It dictates whether the host CPU has privilege to access the 142 // `PGC6_AON_SECURE_SCRATCH_GROUP_05` register (which it needs to read GFW_BOOT). 143 register!(NV_PGC6_AON_SECURE_SCRATCH_GROUP_05_PRIV_LEVEL_MASK @ 0x00118128, 144 "Privilege level mask register" { 145 0:0 read_protection_level0 as bool, "Set after FWSEC lowers its protection level"; 146 }); 147 148 // OpenRM defines this as a register array, but doesn't specify its size and only uses its first 149 // element. Be conservative until we know the actual size or need to use more registers. 150 register!(NV_PGC6_AON_SECURE_SCRATCH_GROUP_05 @ 0x00118234[1] {}); 151 152 register!( 153 NV_PGC6_AON_SECURE_SCRATCH_GROUP_05_0_GFW_BOOT => NV_PGC6_AON_SECURE_SCRATCH_GROUP_05[0], 154 "Scratch group 05 register 0 used as GFW boot progress indicator" { 155 7:0 progress as u8, "Progress of GFW boot (0xff means completed)"; 156 } 157 ); 158 159 impl NV_PGC6_AON_SECURE_SCRATCH_GROUP_05_0_GFW_BOOT { 160 /// Returns `true` if GFW boot is completed. 161 pub(crate) fn completed(self) -> bool { 162 self.progress() == 0xff 163 } 164 } 165 166 register!(NV_PGC6_AON_SECURE_SCRATCH_GROUP_42 @ 0x001183a4 { 167 31:0 value as u32; 168 }); 169 170 register!( 171 NV_USABLE_FB_SIZE_IN_MB => NV_PGC6_AON_SECURE_SCRATCH_GROUP_42, 172 "Scratch group 42 register used as framebuffer size" { 173 31:0 value as u32, "Usable framebuffer size, in megabytes"; 174 } 175 ); 176 177 impl NV_USABLE_FB_SIZE_IN_MB { 178 /// Returns the usable framebuffer size, in bytes. 179 pub(crate) fn usable_fb_size(self) -> u64 { 180 u64::from(self.value()) * u64::from_safe_cast(kernel::sizes::SZ_1M) 181 } 182 } 183 184 // PDISP 185 186 register!(NV_PDISP_VGA_WORKSPACE_BASE @ 0x00625f04 { 187 3:3 status_valid as bool, "Set if the `addr` field is valid"; 188 31:8 addr as u32, "VGA workspace base address divided by 0x10000"; 189 }); 190 191 impl NV_PDISP_VGA_WORKSPACE_BASE { 192 /// Returns the base address of the VGA workspace, or `None` if none exists. 193 pub(crate) fn vga_workspace_addr(self) -> Option<u64> { 194 if self.status_valid() { 195 Some(u64::from(self.addr()) << 16) 196 } else { 197 None 198 } 199 } 200 } 201 202 // FUSE 203 204 pub(crate) const NV_FUSE_OPT_FPF_SIZE: usize = 16; 205 206 register!(NV_FUSE_OPT_FPF_NVDEC_UCODE1_VERSION @ 0x00824100[NV_FUSE_OPT_FPF_SIZE] { 207 15:0 data as u16; 208 }); 209 210 register!(NV_FUSE_OPT_FPF_SEC2_UCODE1_VERSION @ 0x00824140[NV_FUSE_OPT_FPF_SIZE] { 211 15:0 data as u16; 212 }); 213 214 register!(NV_FUSE_OPT_FPF_GSP_UCODE1_VERSION @ 0x008241c0[NV_FUSE_OPT_FPF_SIZE] { 215 15:0 data as u16; 216 }); 217 218 // PFALCON 219 220 register!(NV_PFALCON_FALCON_IRQSCLR @ PFalconBase[0x00000004] { 221 4:4 halt as bool; 222 6:6 swgen0 as bool; 223 }); 224 225 register!(NV_PFALCON_FALCON_MAILBOX0 @ PFalconBase[0x00000040] { 226 31:0 value as u32; 227 }); 228 229 register!(NV_PFALCON_FALCON_MAILBOX1 @ PFalconBase[0x00000044] { 230 31:0 value as u32; 231 }); 232 233 // Used to store version information about the firmware running 234 // on the Falcon processor. 235 register!(NV_PFALCON_FALCON_OS @ PFalconBase[0x00000080] { 236 31:0 value as u32; 237 }); 238 239 register!(NV_PFALCON_FALCON_RM @ PFalconBase[0x00000084] { 240 31:0 value as u32; 241 }); 242 243 register!(NV_PFALCON_FALCON_HWCFG2 @ PFalconBase[0x000000f4] { 244 10:10 riscv as bool; 245 12:12 mem_scrubbing as bool, "Set to 0 after memory scrubbing is completed"; 246 31:31 reset_ready as bool, "Signal indicating that reset is completed (GA102+)"; 247 }); 248 249 impl NV_PFALCON_FALCON_HWCFG2 { 250 /// Returns `true` if memory scrubbing is completed. 251 pub(crate) fn mem_scrubbing_done(self) -> bool { 252 !self.mem_scrubbing() 253 } 254 } 255 256 register!(NV_PFALCON_FALCON_CPUCTL @ PFalconBase[0x00000100] { 257 1:1 startcpu as bool; 258 4:4 halted as bool; 259 6:6 alias_en as bool; 260 }); 261 262 register!(NV_PFALCON_FALCON_BOOTVEC @ PFalconBase[0x00000104] { 263 31:0 value as u32; 264 }); 265 266 register!(NV_PFALCON_FALCON_DMACTL @ PFalconBase[0x0000010c] { 267 0:0 require_ctx as bool; 268 1:1 dmem_scrubbing as bool; 269 2:2 imem_scrubbing as bool; 270 6:3 dmaq_num as u8; 271 7:7 secure_stat as bool; 272 }); 273 274 register!(NV_PFALCON_FALCON_DMATRFBASE @ PFalconBase[0x00000110] { 275 31:0 base as u32; 276 }); 277 278 register!(NV_PFALCON_FALCON_DMATRFMOFFS @ PFalconBase[0x00000114] { 279 23:0 offs as u32; 280 }); 281 282 register!(NV_PFALCON_FALCON_DMATRFCMD @ PFalconBase[0x00000118] { 283 0:0 full as bool; 284 1:1 idle as bool; 285 3:2 sec as u8; 286 4:4 imem as bool; 287 5:5 is_write as bool; 288 10:8 size as u8 ?=> DmaTrfCmdSize; 289 14:12 ctxdma as u8; 290 16:16 set_dmtag as u8; 291 }); 292 293 register!(NV_PFALCON_FALCON_DMATRFFBOFFS @ PFalconBase[0x0000011c] { 294 31:0 offs as u32; 295 }); 296 297 register!(NV_PFALCON_FALCON_DMATRFBASE1 @ PFalconBase[0x00000128] { 298 8:0 base as u16; 299 }); 300 301 register!(NV_PFALCON_FALCON_HWCFG1 @ PFalconBase[0x0000012c] { 302 3:0 core_rev as u8 ?=> FalconCoreRev, "Core revision"; 303 5:4 security_model as u8 ?=> FalconSecurityModel, "Security model"; 304 7:6 core_rev_subversion as u8 ?=> FalconCoreRevSubversion, "Core revision subversion"; 305 }); 306 307 register!(NV_PFALCON_FALCON_CPUCTL_ALIAS @ PFalconBase[0x00000130] { 308 1:1 startcpu as bool; 309 }); 310 311 // Actually known as `NV_PSEC_FALCON_ENGINE` and `NV_PGSP_FALCON_ENGINE` depending on the falcon 312 // instance. 313 register!(NV_PFALCON_FALCON_ENGINE @ PFalconBase[0x000003c0] { 314 0:0 reset as bool; 315 }); 316 317 register!(NV_PFALCON_FBIF_TRANSCFG @ PFalconBase[0x00000600[8]] { 318 1:0 target as u8 ?=> FalconFbifTarget; 319 2:2 mem_type as bool => FalconFbifMemType; 320 }); 321 322 register!(NV_PFALCON_FBIF_CTL @ PFalconBase[0x00000624] { 323 7:7 allow_phys_no_ctx as bool; 324 }); 325 326 /* PFALCON2 */ 327 328 register!(NV_PFALCON2_FALCON_MOD_SEL @ PFalcon2Base[0x00000180] { 329 7:0 algo as u8 ?=> FalconModSelAlgo; 330 }); 331 332 register!(NV_PFALCON2_FALCON_BROM_CURR_UCODE_ID @ PFalcon2Base[0x00000198] { 333 7:0 ucode_id as u8; 334 }); 335 336 register!(NV_PFALCON2_FALCON_BROM_ENGIDMASK @ PFalcon2Base[0x0000019c] { 337 31:0 value as u32; 338 }); 339 340 // OpenRM defines this as a register array, but doesn't specify its size and only uses its first 341 // element. Be conservative until we know the actual size or need to use more registers. 342 register!(NV_PFALCON2_FALCON_BROM_PARAADDR @ PFalcon2Base[0x00000210[1]] { 343 31:0 value as u32; 344 }); 345 346 // PRISCV 347 348 register!(NV_PRISCV_RISCV_CPUCTL @ PFalcon2Base[0x00000388] { 349 0:0 halted as bool; 350 7:7 active_stat as bool; 351 }); 352 353 register!(NV_PRISCV_RISCV_BCR_CTRL @ PFalcon2Base[0x00000668] { 354 0:0 valid as bool; 355 4:4 core_select as bool => PeregrineCoreSelect; 356 8:8 br_fetch as bool; 357 }); 358 359 // The modules below provide registers that are not identical on all supported chips. They should 360 // only be used in HAL modules. 361 362 pub(crate) mod gm107 { 363 // FUSE 364 365 register!(NV_FUSE_STATUS_OPT_DISPLAY @ 0x00021c04 { 366 0:0 display_disabled as bool; 367 }); 368 } 369 370 pub(crate) mod ga100 { 371 // FUSE 372 373 register!(NV_FUSE_STATUS_OPT_DISPLAY @ 0x00820c04 { 374 0:0 display_disabled as bool; 375 }); 376 } 377