Fixes

Fix
Fixes
2025-10-16 08:25:38 +02:00 · 2025-10-16 08:22:10 +02:00 · 2025-10-16 08:18:02 +02:00 · 2025-10-16 08:14:46 +02:00 · 2025-10-16 07:52:58 +02:00
7 changed files with 124 additions and 332 deletions
--- a/build.sh
+++ b/build.sh
@@ -1,24 +1,5 @@
 #!/bin/bash
 print_help() {
  cat << EOF
 Usage: $0 <backends> [build_type]
  <backends>    MANDATORY. Comma-separated list of 
                backends to enable.
                Valid options: hsa, intel, cuda
                Example: hsa,cuda
  [build_type]  OPTIONAL. Build type. Valid options:
                debug, release (default: release)
 Examples:
  $0 hsa,intel debug
  $0 cuda
  $0 hsa,intel,cuda release
 EOF
 }
 # gpufetch build script
 set -e
@@ -26,79 +7,19 @@ rm -rf build/ gpufetch
 mkdir build/
 cd build/
-if [ "$1" == "--help" ]
+if [ "$1" == "debug" ]
 then
-  echo "gpufetch build script"
+  BUILD_TYPE="Debug"
  echo
  print_help
  exit 0
 fi
 if [[ $# -lt 1 ]]; then
  echo "ERROR: At least one backend must be specified."
  echo
  print_help
  exit 1
 fi
 # Determine if last argument is build type
 LAST_ARG="${!#}"
 if [[ "$LAST_ARG" == "debug" || "$LAST_ARG" == "release" ]]; then
  BUILD_TYPE="$LAST_ARG"
  BACKEND_ARG="${1}"
 else
-  BUILD_TYPE="release"
+  BUILD_TYPE="Release"
  BACKEND_ARG="${1}"
 fi
 # Split comma-separated backends into an array
 IFS=',' read -r -a BACKENDS <<< "$BACKEND_ARG"
 # Validate build type 
 if [[ "$BUILD_TYPE" != "debug" && "$BUILD_TYPE" != "release" ]]
 then
  echo "Error: Invalid build type '$BUILD_TYPE'."
  echo "Valid options are: debug, release"
  exit 1
 fi
 # From lower to upper case
 CMAKE_FLAGS="-DCMAKE_BUILD_TYPE=${BUILD_TYPE^}"
 # Validate backends
 VALID_BACKENDS=("hsa" "intel" "cuda")
 for BACKEND in "${BACKENDS[@]}"; do
  case "$BACKEND" in
    hsa)
      CMAKE_FLAGS+=" -DENABLE_HSA_BACKEND=ON"
      ;;
    intel)
      CMAKE_FLAGS+=" -DENABLE_INTEL_BACKEND=ON"
      ;;
    cuda)
      CMAKE_FLAGS+=" -DENABLE_CUDA_BACKEND=ON"
      ;;
    *)
      echo "ERROR: Invalid backend '$BACKEND'."
      echo "Valid options: ${VALID_BACKENDS[*]}"
      exit 1
      ;;
  esac
 done
 # You can also manually specify the compilation flags.
 # If you need to, just run the cmake command directly
 # instead of using this script.
 #
 # Here you will find some help:
 #
 # In case you have CUDA installed but it is not detected,
 # - set CMAKE_CUDA_COMPILER to your nvcc binary:
 # - set CMAKE_CUDA_COMPILER_TOOLKIT_ROOT to the CUDA root dir
 # for example:
 # cmake -DCMAKE_BUILD_TYPE=$BUILD_TYPE -DCMAKE_CUDA_COMPILER=/usr/local/cuda/bin/nvcc -DCMAKE_CUDA_COMPILER_TOOLKIT_ROOT=/usr/local/cuda/ ..
-#
+
 # In case you want to explicitely disable a backend, you can:
 # Disable CUDA backend:
 # cmake -DCMAKE_BUILD_TYPE=$BUILD_TYPE -DENABLE_CUDA_BACKEND=OFF ..
@@ -107,9 +28,7 @@ done
 # Disable Intel backend:
 # cmake -DCMAKE_BUILD_TYPE=$BUILD_TYPE -DENABLE_INTEL_BACKEND=OFF ..
-echo "$0: Running cmake $CMAKE_FLAGS"
+cmake -DCMAKE_BUILD_TYPE=$BUILD_TYPE ..
 echo 
 cmake $CMAKE_FLAGS ..
 os=$(uname)
 if [ "$os" == 'Linux' ]; then
--- a/src/common/gpu.cpp
+++ b/src/common/gpu.cpp
@@ -101,17 +101,6 @@ char* get_str_bus_width(struct gpu_info* gpu) {
  return string;
 }
 char* get_str_lds_size(struct gpu_info* gpu) {
  // TODO: Show XX KB (XX MB Total) like in cpufetch
  uint32_t size = 3+1+3+1;
  assert(strlen(STRING_UNKNOWN)+1 <= size);
  char* string = (char *) ecalloc(size, sizeof(char));
  sprintf(string, "%d KB", gpu->mem->lds_size / 1024);
  return string;
 }
 char* get_str_memory_clock(struct gpu_info* gpu) {
  return get_freq_as_str_mhz(gpu->mem->freq);
 }
--- a/src/common/gpu.hpp
+++ b/src/common/gpu.hpp
@@ -46,10 +46,6 @@ struct topology_c {
 // HSA topology
 struct topology_h {
  int32_t compute_units;
  int32_t num_shader_engines;
  int32_t simds_per_cu;
  int32_t num_xcc;
  int32_t matrix_cores;
 };
 // Intel topology
@@ -65,7 +61,6 @@ struct memory {
  int32_t bus_width;
  int32_t freq;
  int32_t clk_mul; // clock multiplier
  int32_t lds_size; // HSA specific for now
 };
 struct gpu_info {
@@ -93,7 +88,6 @@ char* get_str_freq(struct gpu_info* gpu);
 char* get_str_memory_size(struct gpu_info* gpu);
 char* get_str_memory_type(struct gpu_info* gpu);
 char* get_str_bus_width(struct gpu_info* gpu);
 char* get_str_lds_size(struct gpu_info* gpu);
 char* get_str_memory_clock(struct gpu_info* gpu);
 char* get_str_l2(struct gpu_info* gpu);
 char* get_str_peak_performance(struct gpu_info* gpu);
--- a/src/common/printer.cpp
+++ b/src/common/printer.cpp
@@ -32,60 +32,64 @@
 #define MAX_ATTRIBUTES      100
 #define MAX_TERM_SIZE       1024
 typedef struct {
  int id;
  const char *name;
  const char *shortname;
 } AttributeField;
 // AttributeField IDs
 //                         Used by
 enum {
-  ATTRIBUTE_NAME,          // ALL
+  ATTRIBUTE_NAME,
-  ATTRIBUTE_CHIP,          // ALL
+  ATTRIBUTE_CHIP,
-  ATTRIBUTE_UARCH,         // ALL
+  ATTRIBUTE_UARCH,
-  ATTRIBUTE_TECHNOLOGY,    // ALL
+  ATTRIBUTE_TECHNOLOGY,
-  ATTRIBUTE_FREQUENCY,     // ALL
+  ATTRIBUTE_GT,
-  ATTRIBUTE_PEAK,          // ALL
+  ATTRIBUTE_FREQUENCY,
-  ATTRIBUTE_COMPUTE_UNITS, // HSA
+  ATTRIBUTE_STREAMINGMP,
-  ATTRIBUTE_MATRIX_CORES,  // HSA
+  ATTRIBUTE_CORESPERMP,
-  ATTRIBUTE_XCDS,          // HSA
+  ATTRIBUTE_CUDA_CORES,
-  ATTRIBUTE_LDS_SIZE,      // HSA
+  ATTRIBUTE_TENSOR_CORES,
-  ATTRIBUTE_STREAMINGMP,   // CUDA
+  ATTRIBUTE_EUS,
-  ATTRIBUTE_CORESPERMP,    // CUDA
+  ATTRIBUTE_L2,
-  ATTRIBUTE_CUDA_CORES,    // CUDA
+  ATTRIBUTE_MEMORY,
-  ATTRIBUTE_TENSOR_CORES,  // CUDA
+  ATTRIBUTE_MEMORY_FREQ,
-  ATTRIBUTE_L2,            // CUDA
+  ATTRIBUTE_BUS_WIDTH,
-  ATTRIBUTE_MEMORY,        // CUDA,HSA
+  ATTRIBUTE_PEAK,
-  ATTRIBUTE_MEMORY_FREQ,   // CUDA
+  ATTRIBUTE_PEAK_TENSOR,
  ATTRIBUTE_BUS_WIDTH,     // CUDA,HSA
  ATTRIBUTE_PEAK_TENSOR,   // CUDA
  ATTRIBUTE_EUS,           // Intel
  ATTRIBUTE_GT,            // Intel
 };
-static const AttributeField ATTRIBUTE_INFO[] = {
+static const char* ATTRIBUTE_FIELDS [] = {
-  { ATTRIBUTE_NAME,          "Name:",                   "Name:" },
+  "Name:",
-  { ATTRIBUTE_CHIP,          "GPU processor:",          "Processor:" },
+  "GPU processor:",
-  { ATTRIBUTE_UARCH,         "Microarchitecture:",      "uArch:" },
+  "Microarchitecture:",
-  { ATTRIBUTE_TECHNOLOGY,    "Technology:",             "Technology:" },
+  "Technology:",
-  { ATTRIBUTE_FREQUENCY,     "Max Frequency:",          "Max Freq.:" },
+  "Graphics Tier:",
-  { ATTRIBUTE_PEAK,          "Peak Performance:",       "Peak Perf.:" },
+  "Max Frequency:",
-  { ATTRIBUTE_COMPUTE_UNITS, "Compute Units (CUs):",    "CUs" },
+  "SMs:",
-  { ATTRIBUTE_MATRIX_CORES,  "Matrix Cores:",           "Matrix Cores:" },
+  "Cores/SM:",
-  { ATTRIBUTE_XCDS,          "XCDs:",                   "XCDs" },
+  "CUDA Cores:",
-  { ATTRIBUTE_LDS_SIZE,      "LDS size:",               "LDS:" },
+  "Tensor Cores:",
-  { ATTRIBUTE_STREAMINGMP,   "SMs:",                    "SMs:" },
+  "Execution Units:",
-  { ATTRIBUTE_CORESPERMP,    "Cores/SM:",               "Cores/SM:" },
+  "L2 Size:",
-  { ATTRIBUTE_CUDA_CORES,    "CUDA Cores:",             "CUDA Cores:" },
+  "Memory:",
-  { ATTRIBUTE_TENSOR_CORES,  "Tensor Cores:",           "Tensor Cores:" },
+  "Memory frequency:",
-  { ATTRIBUTE_L2,            "L2 Size:",                "L2 Size:" },
+  "Bus width:",
-  { ATTRIBUTE_MEMORY,        "Memory:",                 "Memory:" },
+  "Peak Performance:",
-  { ATTRIBUTE_MEMORY_FREQ,   "Memory frequency:",       "Memory freq.:" },
+  "Peak Performance (MMA):",
-  { ATTRIBUTE_BUS_WIDTH,     "Bus width:",              "Bus width:" },
+};
-  { ATTRIBUTE_PEAK_TENSOR,   "Peak Performance (MMA):", "Peak Perf.(MMA):" },
+
-  { ATTRIBUTE_EUS,           "Execution Units:",        "EUs:" },
+static const char* ATTRIBUTE_FIELDS_SHORT [] = {
-  { ATTRIBUTE_GT,            "Graphics Tier:",          "GT:" },
+  "Name:",
  "Processor:",
  "uArch:",
  "Technology:",
  "GT:",
  "Max Freq.:",
  "SMs:",
  "Cores/SM:",
  "CUDA Cores:",
  "Tensor Cores:",
  "EUs:",
  "L2 Size:",
  "Memory:",
  "Memory freq.:",
  "Bus width:",
  "Peak Perf.:",
  "Peak Perf.(MMA):",
 };
 struct terminal {
@@ -203,6 +207,8 @@ bool ascii_fits_screen(int termw, struct ascii_logo logo, int lf) {
 void replace_bgbyfg_color(struct ascii_logo* logo) {
  // Replace background by foreground color
  for(int i=0; i < 2; i++) {
    if(logo->color_ascii[i] == NULL) break;
    if(strcmp(logo->color_ascii[i], C_BG_BLACK) == 0) strcpy(logo->color_ascii[i], C_FG_BLACK);
    else if(strcmp(logo->color_ascii[i], C_BG_RED) == 0) strcpy(logo->color_ascii[i], C_FG_RED);
    else if(strcmp(logo->color_ascii[i], C_BG_GREEN) == 0) strcpy(logo->color_ascii[i], C_FG_GREEN);
@@ -270,14 +276,13 @@ void choose_ascii_art(struct ascii* art, struct color** cs, struct terminal* ter
  }
 }
-uint32_t longest_attribute_length(struct ascii* art, bool use_short) {
+uint32_t longest_attribute_length(struct ascii* art, const char** attribute_fields) {
  uint32_t max = 0;
  uint64_t len = 0;
  for(uint32_t i=0; i < art->n_attributes_set; i++) {
    if(art->attributes[i]->value != NULL) {
-      const char* str = use_short ? ATTRIBUTE_INFO[art->attributes[i]->type].shortname : ATTRIBUTE_INFO[art->attributes[i]->type].name;
+      len = strlen(attribute_fields[art->attributes[i]->type]);
      len = strlen(str);
      if(len > max) max = len;
    }
  }
@@ -301,7 +306,7 @@ uint32_t longest_field_length(struct ascii* art, int la) {
  return max;
 }
-void print_ascii_generic(struct ascii* art, uint32_t la, int32_t text_space, bool use_short) {
+void print_ascii_generic(struct ascii* art, uint32_t la, int32_t text_space, const char** attribute_fields) {
  struct ascii_logo* logo = art->art;
  int attr_to_print = 0;
  int attr_type;
@@ -345,13 +350,11 @@ void print_ascii_generic(struct ascii* art, uint32_t la, int32_t text_space, boo
      attr_value = art->attributes[attr_to_print]->value;
      attr_to_print++;
-      const char* attr_str = use_short ? ATTRIBUTE_INFO[attr_type].shortname : ATTRIBUTE_INFO[attr_type].name;
+      space_right = 1 + (la - strlen(attribute_fields[attr_type]));
      space_right = 1 + (la - strlen(attr_str));
      current_space = max(0, text_space);
-      printf("%s%.*s%s", logo->color_text[0], current_space, attr_str, art->reset);
+      printf("%s%.*s%s", logo->color_text[0], current_space, attribute_fields[attr_type], art->reset);
-      current_space = max(0, current_space - (int) strlen(attr_str));
+      current_space = max(0, current_space - (int) strlen(attribute_fields[attr_type]));
      printf("%*s", min(current_space, space_right), "");
      current_space = max(0, current_space - min(current_space, space_right));
      printf("%s%.*s%s", logo->color_text[1], current_space, attr_value, art->reset);
@@ -385,19 +388,19 @@ bool print_gpufetch_intel(struct gpu_info* gpu, STYLE s, struct color** cs, stru
  setAttribute(art, ATTRIBUTE_EUS, eus);
  setAttribute(art, ATTRIBUTE_PEAK, pp);
-  bool use_short = false;
+  const char** attribute_fields = ATTRIBUTE_FIELDS;
-  uint32_t longest_attribute = longest_attribute_length(art, use_short);
+  uint32_t longest_attribute = longest_attribute_length(art, attribute_fields);
  uint32_t longest_field = longest_field_length(art, longest_attribute);
  choose_ascii_art(art, cs, term, longest_field);
  if(!ascii_fits_screen(term->w, *art->art, longest_field)) {
    // Despite of choosing the smallest logo, the output does not fit
    // Choose the shorter field names and recalculate the longest attr
-    use_short = true;
+    attribute_fields = ATTRIBUTE_FIELDS_SHORT;
-    longest_attribute = longest_attribute_length(art, use_short);
+    longest_attribute = longest_attribute_length(art, attribute_fields);
  }
-  print_ascii_generic(art, longest_attribute, term->w - art->art->width, use_short);
+  print_ascii_generic(art, longest_attribute, term->w - art->art->width, attribute_fields);
  return true;
 }
@@ -454,19 +457,19 @@ bool print_gpufetch_cuda(struct gpu_info* gpu, STYLE s, struct color** cs, struc
    setAttribute(art, ATTRIBUTE_PEAK_TENSOR, pp_tensor);
  }
-  bool use_short = false;
+  const char** attribute_fields = ATTRIBUTE_FIELDS;
-  uint32_t longest_attribute = longest_attribute_length(art, use_short);
+  uint32_t longest_attribute = longest_attribute_length(art, attribute_fields);
  uint32_t longest_field = longest_field_length(art, longest_attribute);
  choose_ascii_art(art, cs, term, longest_field);
  if(!ascii_fits_screen(term->w, *art->art, longest_field)) {
    // Despite of choosing the smallest logo, the output does not fit
    // Choose the shorter field names and recalculate the longest attr
-    use_short = true;
+    attribute_fields = ATTRIBUTE_FIELDS_SHORT;
-    longest_attribute = longest_attribute_length(art, use_short);
+    longest_attribute = longest_attribute_length(art, attribute_fields);
  }
-  print_ascii_generic(art, longest_attribute, term->w - art->art->width, use_short);
+  print_ascii_generic(art, longest_attribute, term->w - art->art->width, attribute_fields);
  free(manufacturing_process);
  free(max_frequency);
@@ -491,13 +494,8 @@ bool print_gpufetch_amd(struct gpu_info* gpu, STYLE s, struct color** cs, struct
  char* gpu_chip = get_str_chip(gpu->arch);
  char* uarch = get_str_uarch_hsa(gpu->arch);
  char* manufacturing_process = get_str_process(gpu->arch);
-  char* cus = get_str_cu(gpu);
+  char* sms = get_str_cu(gpu);
  char* matrix_cores = get_str_matrix_cores(gpu);
  char* xcds = get_str_xcds(gpu);
  char* max_frequency = get_str_freq(gpu);
  char* bus_width = get_str_bus_width(gpu);
  char* mem_size = get_str_memory_size(gpu);
  char* lds_size = get_str_lds_size(gpu);
  setAttribute(art, ATTRIBUTE_NAME, gpu_name);
  if (gpu_chip != NULL) {
@@ -506,28 +504,21 @@ bool print_gpufetch_amd(struct gpu_info* gpu, STYLE s, struct color** cs, struct
  setAttribute(art, ATTRIBUTE_UARCH, uarch);
  setAttribute(art, ATTRIBUTE_TECHNOLOGY, manufacturing_process);
  setAttribute(art, ATTRIBUTE_FREQUENCY, max_frequency);
-  setAttribute(art, ATTRIBUTE_COMPUTE_UNITS, cus);
+  setAttribute(art, ATTRIBUTE_STREAMINGMP, sms);
  setAttribute(art, ATTRIBUTE_MATRIX_CORES, matrix_cores);
  if (xcds != NULL) {
    setAttribute(art, ATTRIBUTE_XCDS, xcds);
  }
  setAttribute(art, ATTRIBUTE_LDS_SIZE, lds_size);
  setAttribute(art, ATTRIBUTE_MEMORY, mem_size);
  setAttribute(art, ATTRIBUTE_BUS_WIDTH, bus_width);
-  bool use_short = false;
+  const char** attribute_fields = ATTRIBUTE_FIELDS;
-  uint32_t longest_attribute = longest_attribute_length(art, use_short);
+  uint32_t longest_attribute = longest_attribute_length(art, attribute_fields);
  uint32_t longest_field = longest_field_length(art, longest_attribute);
  choose_ascii_art(art, cs, term, longest_field);
  if(!ascii_fits_screen(term->w, *art->art, longest_field)) {
    // Despite of choosing the smallest logo, the output does not fit
    // Choose the shorter field names and recalculate the longest attr
-    use_short = true;
+    attribute_fields = ATTRIBUTE_FIELDS_SHORT;
-    longest_attribute = longest_attribute_length(art, use_short);
+    longest_attribute = longest_attribute_length(art, attribute_fields);
  }
-  print_ascii_generic(art, longest_attribute, term->w - art->art->width, use_short);
+  print_ascii_generic(art, longest_attribute, term->w - art->art->width, attribute_fields);
  free(art->attributes);
  free(art);
--- a/src/cuda/cuda.cpp
+++ b/src/cuda/cuda.cpp
@@ -1,6 +1,3 @@
 // patched cuda.cpp for cuda13 by cloudy
 #include <cuda_runtime.h>
 #include <cstring>
 #include <cstdlib>
@@ -17,20 +14,25 @@ bool print_gpu_cuda(struct gpu_info* gpu) {
  char* cc = get_str_cc(gpu->arch);
  printf("%s (Compute Capability %s)\n", gpu->name, cc);
  free(cc);
  return true;
 }
 struct cache* get_cache_info(cudaDeviceProp prop) {
  struct cache* cach = (struct cache*) emalloc(sizeof(struct cache));
  cach->L2 = (struct cach*) emalloc(sizeof(struct cach));
  cach->L2->size = prop.l2CacheSize;
  cach->L2->num_caches = 1;
  cach->L2->exists = true;
  return cach;
 }
 int get_tensor_cores(struct uarch* arch, int sm, int major) {
  if(major == 7) {
    // TU116 does not have tensor cores!
    // https://www.anandtech.com/show/13973/nvidia-gtx-1660-ti-review-feat-evga-xc-gaming/2
    if (is_chip_TU116(arch))
      return 0;
    return sm * 8;
@@ -41,57 +43,57 @@ int get_tensor_cores(struct uarch* arch, int sm, int major) {
 struct topology_c* get_topology_info(struct uarch* arch, cudaDeviceProp prop) {
  struct topology_c* topo = (struct topology_c*) emalloc(sizeof(struct topology_c));
  topo->streaming_mp = prop.multiProcessorCount;
  topo->cores_per_mp = _ConvertSMVer2Cores(prop.major, prop.minor);
  topo->cuda_cores = topo->streaming_mp * topo->cores_per_mp;
  topo->tensor_cores = get_tensor_cores(arch, topo->streaming_mp, prop.major);
  return topo;
 }
 int32_t guess_clock_multipilier(struct gpu_info* gpu, struct memory* mem) {
  // Guess clock multiplier
  int32_t clk_mul = 1;
  int32_t clk8 = abs((mem->freq/8) - gpu->freq);
  int32_t clk4 = abs((mem->freq/4) - gpu->freq);
  int32_t clk2 = abs((mem->freq/2) - gpu->freq);
  int32_t clk1 = abs((mem->freq/1) - gpu->freq);
  int32_t min = mem->freq;
  if(clkm_possible_for_uarch(8, gpu->arch) && min > clk8) { clk_mul = 8; min = clk8; }
  if(clkm_possible_for_uarch(4, gpu->arch) && min > clk4) { clk_mul = 4; min = clk4; }
  if(clkm_possible_for_uarch(2, gpu->arch) && min > clk2) { clk_mul = 2; min = clk2; }
  if(clkm_possible_for_uarch(1, gpu->arch) && min > clk1) { clk_mul = 1; min = clk1; }
  return clk_mul;
 }
 struct memory* get_memory_info(struct gpu_info* gpu, cudaDeviceProp prop) {
  struct memory* mem = (struct memory*) emalloc(sizeof(struct memory));
  int val = 0;
  mem->size_bytes = (unsigned long long) prop.totalGlobalMem;
-
+  mem->freq = prop.memoryClockRate * 0.001f;
  if (cudaDeviceGetAttribute(&val, cudaDevAttrMemoryClockRate, gpu->idx) == cudaSuccess) {
      if (val > 1000000)
          mem->freq = (float)val / 1000000.0f;
      else
          mem->freq = (float)val * 0.001f;
  } else {
      mem->freq = 0.0f;
  }
  mem->bus_width = prop.memoryBusWidth;
  mem->clk_mul = guess_clock_multipilier(gpu, mem);
  mem->type = guess_memtype_from_cmul_and_uarch(mem->clk_mul, gpu->arch);
-  if (mem->clk_mul > 0)
+  // Fix frequency returned from CUDA to show real frequency
-      mem->freq = mem->freq / mem->clk_mul;
+  mem->freq = mem->freq  / mem->clk_mul;
  return mem;
 }
 // Compute peak performance when using CUDA cores
 int64_t get_peak_performance_cuda(struct gpu_info* gpu) {
  return gpu->freq * 1000000 * gpu->topo_c->cuda_cores * 2;
 }
 // Compute peak performance when using tensor cores
 int64_t get_peak_performance_tcu(cudaDeviceProp prop, struct gpu_info* gpu) {
  // Volta / Turing tensor cores performs 4x4x4 FP16 matrix multiplication
  // Ampere tensor cores performs 8x4x8 FP16 matrix multiplicacion
  if(prop.major == 7) return gpu->freq * 1000000 * 4 * 4 * 4  * 2 * gpu->topo_c->tensor_cores;
  else if(prop.major == 8) return gpu->freq * 1000000 * 8 * 4 * 8 * 2 * gpu->topo_c->tensor_cores;
  else return 0;
@@ -113,7 +115,8 @@ struct gpu_info* get_gpu_info_cuda(struct pci_dev *devices, int gpu_idx) {
  }
  int num_gpus = -1;
-  cudaError_t err = cudaGetDeviceCount(&num_gpus);
+  cudaError_t err = cudaSuccess;
  err = cudaGetDeviceCount(&num_gpus);
  if(gpu_idx == 0) {
    printf("\r%*c\r", (int) strlen(CUDA_DRIVER_START_WARNING), ' ');
@@ -131,6 +134,7 @@ struct gpu_info* get_gpu_info_cuda(struct pci_dev *devices, int gpu_idx) {
  }
  if(gpu->idx+1 > num_gpus) {
    // Master is trying to query an invalid GPU
    return NULL;
  }
@@ -140,25 +144,15 @@ struct gpu_info* get_gpu_info_cuda(struct pci_dev *devices, int gpu_idx) {
    return NULL;
  }
-  int core_clk = 0;
+  gpu->freq = deviceProp.clockRate * 1e-3f;
  if (cudaDeviceGetAttribute(&core_clk, cudaDevAttrClockRate, gpu->idx) == cudaSuccess) {
      if (core_clk > 1000000)
          gpu->freq = core_clk / 1000000.0f;
      else
          gpu->freq = core_clk * 0.001f;
  } else {
      gpu->freq = 0.0f;
  }
  gpu->vendor = GPU_VENDOR_NVIDIA;
-  gpu->name = (char *) emalloc(strlen(deviceProp.name) + 1);
+  gpu->name = (char *) emalloc(sizeof(char) * (strlen(deviceProp.name) + 1));
  strcpy(gpu->name, deviceProp.name);
  if((gpu->pci = get_pci_from_pciutils(devices, PCI_VENDOR_ID_NVIDIA, gpu_idx)) == NULL) {
    printErr("Unable to find a valid device for vendor id 0x%.4X using pciutils", PCI_VENDOR_ID_NVIDIA);
    return NULL;
  }
  gpu->arch = get_uarch_from_cuda(gpu);
  gpu->cach = get_cache_info(deviceProp);
  gpu->mem = get_memory_info(gpu, deviceProp);
@@ -169,7 +163,19 @@ struct gpu_info* get_gpu_info_cuda(struct pci_dev *devices, int gpu_idx) {
  return gpu;
 }
-char* get_str_sm(struct gpu_info* gpu) { return get_str_generic(gpu->topo_c->streaming_mp); }
+char* get_str_sm(struct gpu_info* gpu) {
-char* get_str_cores_sm(struct gpu_info* gpu) { return get_str_generic(gpu->topo_c->cores_per_mp); }
+  return get_str_generic(gpu->topo_c->streaming_mp);
-char* get_str_cuda_cores(struct gpu_info* gpu) { return get_str_generic(gpu->topo_c->cuda_cores); }
+}
-char* get_str_tensor_cores(struct gpu_info* gpu) { return get_str_generic(gpu->topo_c->tensor_cores); }
+
 char* get_str_cores_sm(struct gpu_info* gpu) {
  return get_str_generic(gpu->topo_c->cores_per_mp);
 }
 char* get_str_cuda_cores(struct gpu_info* gpu) {
  return get_str_generic(gpu->topo_c->cuda_cores);
 }
 char* get_str_tensor_cores(struct gpu_info* gpu) {
  return get_str_generic(gpu->topo_c->tensor_cores);
 }
--- a/src/hsa/hsa.cpp
+++ b/src/hsa/hsa.cpp
@@ -22,16 +22,7 @@ struct agent_info {
  char vendor_name[64];
  char device_mkt_name[64];
  uint32_t max_clock_freq;
  // Memory
  uint32_t bus_width;
  uint32_t lds_size;
  uint64_t global_size;
  // Topology
  uint32_t compute_unit;
  uint32_t num_shader_engines;
  uint32_t simds_per_cu;
  uint32_t num_xcc;            // Acccelerator Complex Dies (XCDs)
  uint32_t matrix_cores;       // Cores with WMMA/MFMA capabilities
 };
 #define RET_IF_HSA_ERR(err) { \
@@ -49,51 +40,6 @@ struct agent_info {
  }                                                                           \
 }
 hsa_status_t memory_pool_callback(hsa_amd_memory_pool_t pool, void* data) {
  struct agent_info* info = reinterpret_cast<struct agent_info *>(data);
  hsa_amd_segment_t segment;
  hsa_status_t err = hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_SEGMENT, &segment);
  RET_IF_HSA_ERR(err);
  if (segment == HSA_AMD_SEGMENT_GROUP) {
    // LDS memory
    // We want to make sure that this memory pool is not repeated.
    if (info->lds_size != 0) {
      printErr("Found HSA_AMD_SEGMENT_GROUP twice!");
      return HSA_STATUS_ERROR;
    }
    uint32_t size = 0;
    err = hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_SIZE, &size);
    RET_IF_HSA_ERR(err);
    info->lds_size = size;    
  }
  else if (segment == HSA_AMD_SEGMENT_GLOBAL) {
    // Global memory
    uint32_t global_flags = 0;
    err = hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_GLOBAL_FLAGS, &global_flags);
    RET_IF_HSA_ERR(err);
    if (global_flags & HSA_AMD_MEMORY_POOL_GLOBAL_FLAG_EXTENDED_SCOPE_FINE_GRAINED) {
      if (info->global_size != 0) {
        printErr("Found HSA_AMD_MEMORY_POOL_GLOBAL_FLAG_EXTENDED_SCOPE_FINE_GRAINED twice!");
        return HSA_STATUS_ERROR;
      }
      uint64_t size = 0;
      err = hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_SIZE, &size);
      RET_IF_HSA_ERR(err);
      info->global_size = size;
    }    
  }
  return HSA_STATUS_SUCCESS;
 }
 hsa_status_t agent_callback(hsa_agent_t agent, void *data) {
  struct agent_info* info = reinterpret_cast<struct agent_info *>(data);
@@ -116,26 +62,6 @@ hsa_status_t agent_callback(hsa_agent_t agent, void *data) {
    err = hsa_agent_get_info(agent, (hsa_agent_info_t) HSA_AMD_AGENT_INFO_COMPUTE_UNIT_COUNT, &info->compute_unit);
    RET_IF_HSA_ERR(err);
    // According to the documentation, this is deprecated. But what should I be using then?
    err = hsa_agent_get_info(agent, (hsa_agent_info_t) HSA_AMD_AGENT_INFO_MEMORY_WIDTH, &info->bus_width);
    RET_IF_HSA_ERR(err);
    err = hsa_agent_get_info(agent, (hsa_agent_info_t) HSA_AMD_AGENT_INFO_NUM_SHADER_ENGINES, &info->num_shader_engines);
    RET_IF_HSA_ERR(err);
    err = hsa_agent_get_info(agent, (hsa_agent_info_t) HSA_AMD_AGENT_INFO_NUM_SIMDS_PER_CU, &info->simds_per_cu);
    RET_IF_HSA_ERR(err);
    err = hsa_agent_get_info(agent, (hsa_agent_info_t) HSA_AMD_AGENT_INFO_NUM_XCC, &info->num_xcc);
    RET_IF_HSA_ERR(err);
    // We will check against zero to see if it was set beforehand.
    info->global_size = 0;
    info->lds_size = 0;
    // This will fill global_size and lds_size.
    err = hsa_amd_agent_iterate_memory_pools(agent, memory_pool_callback, data);
    RET_IF_HSA_ERR(err);
  }
  return HSA_STATUS_SUCCESS;
@@ -145,26 +71,10 @@ struct topology_h* get_topology_info(struct agent_info info) {
  struct topology_h* topo = (struct topology_h*) emalloc(sizeof(struct topology_h));
  topo->compute_units = info.compute_unit;
  topo->num_shader_engines = info.num_shader_engines; // not printed at the moment
  topo->simds_per_cu = info.simds_per_cu;             // not printed at the moment
  topo->num_xcc = info.num_xcc;
  // Old GPUs (GCN I guess) might not have matrix cores.
  // Not sure what would happen here?
  topo->matrix_cores = topo->compute_units * topo->simds_per_cu;
  return topo;
 }
 struct memory* get_memory_info(struct gpu_info* gpu, struct agent_info info) {
  struct memory* mem = (struct memory*) emalloc(sizeof(struct memory));
  mem->bus_width = info.bus_width;
  mem->lds_size = info.lds_size;
  mem->size_bytes = info.global_size;
  return mem;
 }
 struct gpu_info* get_gpu_info_hsa(int gpu_idx) {
  struct gpu_info* gpu = (struct gpu_info*) emalloc(sizeof(struct gpu_info));
  gpu->pci = NULL;
@@ -208,7 +118,6 @@ struct gpu_info* get_gpu_info_hsa(int gpu_idx) {
  gpu->name = (char *) emalloc(sizeof(char) * (strlen(info.device_mkt_name) + 1));
  strcpy(gpu->name, info.device_mkt_name);
  gpu->arch = get_uarch_from_hsa(gpu, info.gpu_name);
  gpu->mem = get_memory_info(gpu, info);
  if (gpu->arch == NULL) {
    return NULL;
@@ -226,17 +135,3 @@ struct gpu_info* get_gpu_info_hsa(int gpu_idx) {
 char* get_str_cu(struct gpu_info* gpu) {
  return get_str_generic(gpu->topo_h->compute_units);
 }
 char* get_str_xcds(struct gpu_info* gpu) {
  // If there is a single XCD, then we dont want to
  // print it.
  if (gpu->topo_h->num_xcc == 1) {
    return NULL;
  }
  return get_str_generic(gpu->topo_h->num_xcc);
 }
 char* get_str_matrix_cores(struct gpu_info* gpu) {
  // TODO: Show XX (WMMA/MFMA)
  return get_str_generic(gpu->topo_h->matrix_cores);
 }
--- a/src/hsa/hsa.hpp
+++ b/src/hsa/hsa.hpp
@@ -5,7 +5,5 @@
 struct gpu_info* get_gpu_info_hsa(int gpu_idx);
 char* get_str_cu(struct gpu_info* gpu);
 char* get_str_xcds(struct gpu_info* gpu);
 char* get_str_matrix_cores(struct gpu_info* gpu);
 #endif
Author	SHA1	Message	Date
Dr-Noob	bc6e3b35e9	Fixes	2025-10-16 08:25:38 +02:00
Dr-Noob	8c81067577	Fix	2025-10-16 08:22:10 +02:00
Dr-Noob	462f61ce40	Fixes	2025-10-16 08:18:02 +02:00
Dr-Noob	7c361ee879	Not sure this is what we want	2025-10-16 08:14:46 +02:00
Dr-Noob	e0b0a6913c	Build pciutils only if neccesary	2025-10-16 07:52:58 +02:00